extending

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Extending and Embedding Python Release 3.1.3

Guido van Rossum Fred L. Drake, Jr., editor

February 09, 2011

Python Software Foundation Email: docs@python.org



CONTENTS

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Extending Python with C or C++ 1.1 A Simple Example . . . . . . . . . . . . . . . . . . . . 1.2 Intermezzo: Errors and Exceptions . . . . . . . . . . . 1.3 Back to the Example . . . . . . . . . . . . . . . . . . . 1.4 The Module’s Method Table and Initialization Function 1.5 Compilation and Linkage . . . . . . . . . . . . . . . . 1.6 Calling Python Functions from C . . . . . . . . . . . . 1.7 Extracting Parameters in Extension Functions . . . . . . 1.8 Keyword Parameters for Extension Functions . . . . . . 1.9 Building Arbitrary Values . . . . . . . . . . . . . . . . 1.10 Reference Counts . . . . . . . . . . . . . . . . . . . . . 1.11 Writing Extensions in C++ . . . . . . . . . . . . . . . . 1.12 Providing a C API for an Extension Module . . . . . . .

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3 3 4 6 7 8 9 11 12 13 14 17 17

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Defining New Types 2.1 The Basics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2 Type Methods . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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Building C and C++ Extensions with distutils 3.1 Distributing your extension modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

61 62

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Building C and C++ Extensions on Windows 4.1 A Cookbook Approach . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2 Differences Between Unix and Windows . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3 Using DLLs in Practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

63 63 65 66

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Embedding Python in Another Application 5.1 Very High Level Embedding . . . . . . . . . . . . 5.2 Beyond Very High Level Embedding: An overview 5.3 Pure Embedding . . . . . . . . . . . . . . . . . . 5.4 Extending Embedded Python . . . . . . . . . . . 5.5 Embedding Python in C++ . . . . . . . . . . . . . 5.6 Linking Requirements . . . . . . . . . . . . . . .

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A Glossary

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B About these documents B.1 Contributors to the Python Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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C History and License

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C.1 C.2 C.3

History of the software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Terms and conditions for accessing or otherwise using Python . . . . . . . . . . . . . . . . . . . . . Licenses and Acknowledgements for Incorporated Software . . . . . . . . . . . . . . . . . . . . . .

D Copyright Index

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83 84 86 99 101


Extending and Embedding Python, Release 3.1.3

Release 3.1 Date February 09, 2011 This document describes how to write modules in C or C++ to extend the Python interpreter with new modules. Those modules can define new functions but also new object types and their methods. The document also describes how to embed the Python interpreter in another application, for use as an extension language. Finally, it shows how to compile and link extension modules so that they can be loaded dynamically (at run time) into the interpreter, if the underlying operating system supports this feature. This document assumes basic knowledge about Python. For an informal introduction to the language, see The Python Tutorial (in Python Tutorial). The Python Language Reference (in The Python Language Reference) gives a more formal definition of the language. The Python Standard Library (in The Python Library Reference) documents the existing object types, functions and modules (both built-in and written in Python) that give the language its wide application range. For a detailed description of the whole Python/C API, see the separate Python/C API Reference Manual (in The Python/C API).

CONTENTS

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Extending and Embedding Python, Release 3.1.3

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CONTENTS


CHAPTER

ONE

EXTENDING PYTHON WITH C OR C++ It is quite easy to add new built-in modules to Python, if you know how to program in C. Such extension modules can do two things that can’t be done directly in Python: they can implement new built-in object types, and they can call C library functions and system calls. To support extensions, the Python API (Application Programmers Interface) defines a set of functions, macros and variables that provide access to most aspects of the Python run-time system. The Python API is incorporated in a C source file by including the header "Python.h". The compilation of an extension module depends on its intended use as well as on your system setup; details are given in later chapters.

1.1 A Simple Example Let’s create an extension module called spam (the favorite food of Monty Python fans...) and let’s say we want to create a Python interface to the C library function system(). 1 This function takes a null-terminated character string as argument and returns an integer. We want this function to be callable from Python as follows: >>> import spam >>> status = spam.system("ls -l") Begin by creating a file spammodule.c. (Historically, if a module is called spam, the C file containing its implementation is called spammodule.c; if the module name is very long, like spammify, the module name can be just spammify.c.) The first line of our file can be: #include <Python.h> which pulls in the Python API (you can add a comment describing the purpose of the module and a copyright notice if you like). Note: Since Python may define some pre-processor definitions which affect the standard headers on some systems, you must include Python.h before any standard headers are included. All user-visible symbols defined by Python.h have a prefix of Py or PY, except those defined in standard header files. For convenience, and since they are used extensively by the Python interpreter, "Python.h" includes a few standard header files: <stdio.h>, <string.h>, <errno.h>, and <stdlib.h>. If the latter header file does not exist on your system, it declares the functions malloc(), free() and realloc() directly. The next thing we add to our module file is the C function that will be called when the Python expression spam.system(string) is evaluated (we’ll see shortly how it ends up being called): 1

An interface for this function already exists in the standard module os — it was chosen as a simple and straightforward example.

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static PyObject * spam_system(PyObject *self, PyObject *args) { const char *command; int sts; if (!PyArg_ParseTuple(args, "s", &command)) return NULL; sts = system(command); return PyLong_FromLong(sts); } There is a straightforward translation from the argument list in Python (for example, the single expression "ls -l") to the arguments passed to the C function. The C function always has two arguments, conventionally named self and args. The self argument points to the module object for module-level functions; for a method it would point to the object instance. The args argument will be a pointer to a Python tuple object containing the arguments. Each item of the tuple corresponds to an argument in the call’s argument list. The arguments are Python objects — in order to do anything with them in our C function we have to convert them to C values. The function PyArg_ParseTuple() in the Python API checks the argument types and converts them to C values. It uses a template string to determine the required types of the arguments as well as the types of the C variables into which to store the converted values. More about this later. PyArg_ParseTuple() returns true (nonzero) if all arguments have the right type and its components have been stored in the variables whose addresses are passed. It returns false (zero) if an invalid argument list was passed. In the latter case it also raises an appropriate exception so the calling function can return NULL immediately (as we saw in the example).

1.2 Intermezzo: Errors and Exceptions An important convention throughout the Python interpreter is the following: when a function fails, it should set an exception condition and return an error value (usually a NULL pointer). Exceptions are stored in a static global variable inside the interpreter; if this variable is NULL no exception has occurred. A second global variable stores the “associated value” of the exception (the second argument to raise). A third variable contains the stack traceback in case the error originated in Python code. These three variables are the C equivalents of the result in Python of sys.exc_info() (see the section on module sys in the Python Library Reference). It is important to know about them to understand how errors are passed around. The Python API defines a number of functions to set various types of exceptions. The most common one is PyErr_SetString(). Its arguments are an exception object and a C string. The exception object is usually a predefined object like PyExc_ZeroDivisionError. The C string indicates the cause of the error and is converted to a Python string object and stored as the “associated value” of the exception. Another useful function is PyErr_SetFromErrno(), which only takes an exception argument and constructs the associated value by inspection of the global variable errno. The most general function is PyErr_SetObject(), which takes two object arguments, the exception and its associated value. You don’t need to Py_INCREF() the objects passed to any of these functions. You can test non-destructively whether an exception has been set with PyErr_Occurred(). This returns the current exception object, or NULL if no exception has occurred. You normally don’t need to call PyErr_Occurred() to see whether an error occurred in a function call, since you should be able to tell from the return value.

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When a function f that calls another function g detects that the latter fails, f should itself return an error value (usually NULL or -1). It should not call one of the PyErr_*() functions — one has already been called by g. f ‘s caller is then supposed to also return an error indication to its caller, again without calling PyErr_*(), and so on — the most detailed cause of the error was already reported by the function that first detected it. Once the error reaches the Python interpreter’s main loop, this aborts the currently executing Python code and tries to find an exception handler specified by the Python programmer. (There are situations where a module can actually give a more detailed error message by calling another PyErr_*() function, and in such cases it is fine to do so. As a general rule, however, this is not necessary, and can cause information about the cause of the error to be lost: most operations can fail for a variety of reasons.) To ignore an exception set by a function call that failed, the exception condition must be cleared explicitly by calling PyErr_Clear(). The only time C code should call PyErr_Clear() is if it doesn’t want to pass the error on to the interpreter but wants to handle it completely by itself (possibly by trying something else, or pretending nothing went wrong). Every failing malloc() call must be turned into an exception — the direct caller of malloc() (or realloc()) must call PyErr_NoMemory() and return a failure indicator itself. All the object-creating functions (for example, PyLong_FromLong()) already do this, so this note is only relevant to those who call malloc() directly. Also note that, with the important exception of PyArg_ParseTuple() and friends, functions that return an integer status usually return a positive value or zero for success and -1 for failure, like Unix system calls. Finally, be careful to clean up garbage (by making Py_XDECREF() or Py_DECREF() calls for objects you have already created) when you return an error indicator! The choice of which exception to raise is entirely yours. There are predeclared C objects corresponding to all built-in Python exceptions, such as PyExc_ZeroDivisionError, which you can use directly. Of course, you should choose exceptions wisely — don’t use PyExc_TypeError to mean that a file couldn’t be opened (that should probably be PyExc_IOError). If something’s wrong with the argument list, the PyArg_ParseTuple() function usually raises PyExc_TypeError. If you have an argument whose value must be in a particular range or must satisfy other conditions, PyExc_ValueError is appropriate. You can also define a new exception that is unique to your module. For this, you usually declare a static object variable at the beginning of your file: static PyObject *SpamError; and initialize it in your module’s initialization function (PyInit_spam()) with an exception object (leaving out the error checking for now): PyMODINIT_FUNC PyInit_spam(void) { PyObject *m; m = PyModule_Create(&spammodule); if (m == NULL) return NULL; SpamError = PyErr_NewException("spam.error", NULL, NULL); Py_INCREF(SpamError); PyModule_AddObject(m, "error", SpamError); return m; } Note that the Python name for the exception object is spam.error. The PyErr_NewException() function may create a class with the base class being Exception (unless another class is passed in instead of NULL), described in Built-in Exceptions (in The Python Library Reference).

1.2. Intermezzo: Errors and Exceptions

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Note also that the SpamError variable retains a reference to the newly created exception class; this is intentional! Since the exception could be removed from the module by external code, an owned reference to the class is needed to ensure that it will not be discarded, causing SpamError to become a dangling pointer. Should it become a dangling pointer, C code which raises the exception could cause a core dump or other unintended side effects. We discuss the use of PyMODINIT_FUNC as a function return type later in this sample. The spam.error exception can be raised in your extension module using a call to PyErr_SetString() as shown below: static PyObject * spam_system(PyObject *self, PyObject *args) { const char *command; int sts; if (!PyArg_ParseTuple(args, "s", &command)) return NULL; sts = system(command); if (sts < 0) { PyErr_SetString(SpamError, "System command failed"); return NULL; } return PyLong_FromLong(sts); }

1.3 Back to the Example Going back to our example function, you should now be able to understand this statement: if (!PyArg_ParseTuple(args, "s", &command)) return NULL; It returns NULL (the error indicator for functions returning object pointers) if an error is detected in the argument list, relying on the exception set by PyArg_ParseTuple(). Otherwise the string value of the argument has been copied to the local variable command. This is a pointer assignment and you are not supposed to modify the string to which it points (so in Standard C, the variable command should properly be declared as const char *command). The next statement is a call to the Unix function system(), passing it the string we just got from PyArg_ParseTuple(): sts = system(command); Our spam.system() function must return the value of sts as a Python object. This is done using the function PyLong_FromLong(). return PyLong_FromLong(sts); In this case, it will return an integer object. (Yes, even integers are objects on the heap in Python!) If you have a C function that returns no useful argument (a function returning void), the corresponding Python function must return None. You need this idiom to do so (which is implemented by the Py_RETURN_NONE macro): Py_INCREF(Py_None); return Py_None; Py_None is the C name for the special Python object None. It is a genuine Python object rather than a NULL pointer, which means “error� in most contexts, as we have seen.

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1.4 The Module’s Method Table and Initialization Function I promised to show how spam_system() is called from Python programs. First, we need to list its name and address in a “method table”: static PyMethodDef SpamMethods[] = { ... {"system", spam_system, METH_VARARGS, "Execute a shell command."}, ... {NULL, NULL, 0, NULL} /* Sentinel */ }; Note the third entry (METH_VARARGS). This is a flag telling the interpreter the calling convention to be used for the C function. It should normally always be METH_VARARGS or METH_VARARGS | METH_KEYWORDS; a value of 0 means that an obsolete variant of PyArg_ParseTuple() is used. When using only METH_VARARGS, the function should expect the Python-level parameters to be passed in as a tuple acceptable for parsing via PyArg_ParseTuple(); more information on this function is provided below. The METH_KEYWORDS bit may be set in the third field if keyword arguments should be passed to the function. In this case, the C function should accept a third PyObject \* parameter which will be a dictionary of keywords. Use PyArg_ParseTupleAndKeywords() to parse the arguments to such a function. The method table must be referenced in the module definition structure: static struct PyModuleDef spammodule = { PyModuleDef_HEAD_INIT, "spam", /* name of module */ spam_doc, /* module documentation, may be NULL */ -1, /* size of per-interpreter state of the module, or -1 if the module keeps state in global variables. */ SpamMethods }; This structure, in turn, must be passed to the interpreter in the module’s initialization function. The initialization function must be named PyInit_name(), where name is the name of the module, and should be the only nonstatic item defined in the module file: PyMODINIT_FUNC PyInit_spam(void) { return PyModule_Create(&spammodule); } Note that PyMODINIT_FUNC declares the function as PyObject * return type, declares any special linkage declarations required by the platform, and for C++ declares the function as extern "C". When the Python program imports module spam for the first time, PyInit_spam() is called. (See below for comments about embedding Python.) It calls PyModule_Create(), which returns a module object, and inserts built-in function objects into the newly created module based upon the table (an array of PyMethodDef structures) found in the module definition. PyModule_Create() returns a pointer to the module object that it creates. It may abort with a fatal error for certain errors, or return NULL if the module could not be initialized satisfactorily. The init function must return the module object to its caller, so that it then gets inserted into sys.modules. When embedding Python, the PyInit_spam() function is not called automatically unless there’s an entry in the PyImport_Inittab table. To add the module to the initialization table, use PyImport_AppendInittab(), optionally followed by an import of the module:

1.4. The Module’s Method Table and Initialization Function

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int main(int argc, char *argv[]) { /* Add a builtin module, before Py_Initialize */ PyImport_AppendInittab("spam", PyInit_spam); /* Pass argv[0] to the Python interpreter */ Py_SetProgramName(argv[0]); /* Initialize the Python interpreter. Py_Initialize();

Required. */

/* Optionally import the module; alternatively, import can be deferred until the embedded script imports it. */ PyImport_ImportModule("spam"); An example may be found in the file Demo/embed/demo.c in the Python source distribution. Note: Removing entries from sys.modules or importing compiled modules into multiple interpreters within a process (or following a fork() without an intervening exec()) can create problems for some extension modules. Extension module authors should exercise caution when initializing internal data structures. A more substantial example module is included in the Python source distribution as Modules/xxmodule.c. This file may be used as a template or simply read as an example. The modulator.py script included in the source distribution or Windows install provides a simple graphical user interface for declaring the functions and objects which a module should implement, and can generate a template which can be filled in. The script lives in the Tools/modulator/ directory; see the README file there for more information.

1.5 Compilation and Linkage There are two more things to do before you can use your new extension: compiling and linking it with the Python system. If you use dynamic loading, the details may depend on the style of dynamic loading your system uses; see the chapters about building extension modules (chapter Building C and C++ Extensions with distutils) and additional information that pertains only to building on Windows (chapter Building C and C++ Extensions on Windows) for more information about this. If you can’t use dynamic loading, or if you want to make your module a permanent part of the Python interpreter, you will have to change the configuration setup and rebuild the interpreter. Luckily, this is very simple on Unix: just place your file (spammodule.c for example) in the Modules/ directory of an unpacked source distribution, add a line to the file Modules/Setup.local describing your file: spam spammodule.o and rebuild the interpreter by running make in the toplevel directory. You can also run make in the Modules/ subdirectory, but then you must first rebuild Makefile there by running ‘make Makefile’. (This is necessary each time you change the Setup file.) If your module requires additional libraries to link with, these can be listed on the line in the configuration file as well, for instance: spam spammodule.o -lX11

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1.6 Calling Python Functions from C So far we have concentrated on making C functions callable from Python. The reverse is also useful: calling Python functions from C. This is especially the case for libraries that support so-called “callback” functions. If a C interface makes use of callbacks, the equivalent Python often needs to provide a callback mechanism to the Python programmer; the implementation will require calling the Python callback functions from a C callback. Other uses are also imaginable. Fortunately, the Python interpreter is easily called recursively, and there is a standard interface to call a Python function. (I won’t dwell on how to call the Python parser with a particular string as input — if you’re interested, have a look at the implementation of the -c command line option in Modules/main.c from the Python source code.) Calling a Python function is easy. First, the Python program must somehow pass you the Python function object. You should provide a function (or some other interface) to do this. When this function is called, save a pointer to the Python function object (be careful to Py_INCREF() it!) in a global variable — or wherever you see fit. For example, the following function might be part of a module definition: static PyObject *my_callback = NULL; static PyObject * my_set_callback(PyObject *dummy, PyObject *args) { PyObject *result = NULL; PyObject *temp; if (PyArg_ParseTuple(args, "O:set_callback", &temp)) { if (!PyCallable_Check(temp)) { PyErr_SetString(PyExc_TypeError, "parameter must be callable"); return NULL; } Py_XINCREF(temp); /* Add a reference to new callback */ Py_XDECREF(my_callback); /* Dispose of previous callback */ my_callback = temp; /* Remember new callback */ /* Boilerplate to return "None" */ Py_INCREF(Py_None); result = Py_None; } return result; } This function must be registered with the interpreter using the METH_VARARGS flag; this is described in section The Module’s Method Table and Initialization Function. The PyArg_ParseTuple() function and its arguments are documented in section Extracting Parameters in Extension Functions. The macros Py_XINCREF() and Py_XDECREF() increment/decrement the reference count of an object and are safe in the presence of NULL pointers (but note that temp will not be NULL in this context). More info on them in section Reference Counts. Later, when it is time to call the function, you call the C function PyObject_CallObject(). This function has two arguments, both pointers to arbitrary Python objects: the Python function, and the argument list. The argument list must always be a tuple object, whose length is the number of arguments. To call the Python function with no arguments, pass in NULL, or an empty tuple; to call it with one argument, pass a singleton tuple. Py_BuildValue() returns a tuple when its format string consists of zero or more format codes between parentheses. For example: int arg; PyObject *arglist; PyObject *result;

1.6. Calling Python Functions from C

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... arg = 123; ... /* Time to call the callback */ arglist = Py_BuildValue("(i)", arg); result = PyObject_CallObject(my_callback, arglist); Py_DECREF(arglist); PyObject_CallObject() returns a Python object pointer: this is the return value of the Python function. PyObject_CallObject() is “reference-count-neutral” with respect to its arguments. In the example a new tuple was created to serve as the argument list, which is Py_DECREF()-ed immediately after the call. The return value of PyObject_CallObject() is “new”: either it is a brand new object, or it is an existing object whose reference count has been incremented. So, unless you want to save it in a global variable, you should somehow Py_DECREF() the result, even (especially!) if you are not interested in its value. Before you do this, however, it is important to check that the return value isn’t NULL. If it is, the Python function terminated by raising an exception. If the C code that called PyObject_CallObject() is called from Python, it should now return an error indication to its Python caller, so the interpreter can print a stack trace, or the calling Python code can handle the exception. If this is not possible or desirable, the exception should be cleared by calling PyErr_Clear(). For example: if (result == NULL) return NULL; /* Pass error back */ ...use result... Py_DECREF(result); Depending on the desired interface to the Python callback function, you may also have to provide an argument list to PyObject_CallObject(). In some cases the argument list is also provided by the Python program, through the same interface that specified the callback function. It can then be saved and used in the same manner as the function object. In other cases, you may have to construct a new tuple to pass as the argument list. The simplest way to do this is to call Py_BuildValue(). For example, if you want to pass an integral event code, you might use the following code: PyObject *arglist; ... arglist = Py_BuildValue("(l)", eventcode); result = PyObject_CallObject(my_callback, arglist); Py_DECREF(arglist); if (result == NULL) return NULL; /* Pass error back */ /* Here maybe use the result */ Py_DECREF(result); Note the placement of Py_DECREF(arglist) immediately after the call, before the error check! Also note that strictly speaking this code is not complete: Py_BuildValue() may run out of memory, and this should be checked. You may also call a function with keyword arguments by using PyObject_Call(), which supports arguments and keyword arguments. As in the above example, we use Py_BuildValue() to construct the dictionary. PyObject *dict; ... dict = Py_BuildValue("{s:i}", "name", val); result = PyObject_Call(my_callback, NULL, dict); Py_DECREF(dict); if (result == NULL) return NULL; /* Pass error back */ /* Here maybe use the result */

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Py_DECREF(result);

1.7 Extracting Parameters in Extension Functions The PyArg_ParseTuple() function is declared as follows: int PyArg_ParseTuple(PyObject *arg, char *format, ...); The arg argument must be a tuple object containing an argument list passed from Python to a C function. The format argument must be a format string, whose syntax is explained in Parsing arguments and building values (in The Python/C API) in the Python/C API Reference Manual. The remaining arguments must be addresses of variables whose type is determined by the format string. Note that while PyArg_ParseTuple() checks that the Python arguments have the required types, it cannot check the validity of the addresses of C variables passed to the call: if you make mistakes there, your code will probably crash or at least overwrite random bits in memory. So be careful! Note that any Python object references which are provided to the caller are borrowed references; do not decrement their reference count! Some example calls: #define PY_SSIZE_T_CLEAN #include <Python.h>

/* Make "s#" use Py_ssize_t rather than int. */

int ok; int i, j; long k, l; const char *s; Py_ssize_t size; ok = PyArg_ParseTuple(args, ""); /* No arguments */ /* Python call: f() */ ok = PyArg_ParseTuple(args, "s", &s); /* A string */ /* Possible Python call: f(’whoops!’) */ ok = PyArg_ParseTuple(args, "lls", &k, &l, &s); /* Two longs and a string */ /* Possible Python call: f(1, 2, ’three’) */ ok = PyArg_ParseTuple(args, "(ii)s#", &i, &j, &s, &size); /* A pair of ints and a string, whose size is also returned */ /* Possible Python call: f((1, 2), ’three’) */ { const char *file; const char *mode = "r"; int bufsize = 0; ok = PyArg_ParseTuple(args, "s|si", &file, &mode, &bufsize); /* A string, and optionally another string and an integer */ /* Possible Python calls: f(’spam’) f(’spam’, ’w’) f(’spam’, ’wb’, 100000) */ } { int left, top, right, bottom, h, v;

1.7. Extracting Parameters in Extension Functions

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ok = PyArg_ParseTuple(args, "((ii)(ii))(ii)", &left, &top, &right, &bottom, &h, &v); /* A rectangle and a point */ /* Possible Python call: f(((0, 0), (400, 300)), (10, 10)) */ } { Py_complex c; ok = PyArg_ParseTuple(args, "D:myfunction", &c); /* a complex, also providing a function name for errors */ /* Possible Python call: myfunction(1+2j) */ }

1.8 Keyword Parameters for Extension Functions The PyArg_ParseTupleAndKeywords() function is declared as follows: int PyArg_ParseTupleAndKeywords(PyObject *arg, PyObject *kwdict, char *format, char *kwlist[], ...); The arg and format parameters are identical to those of the PyArg_ParseTuple() function. The kwdict parameter is the dictionary of keywords received as the third parameter from the Python runtime. The kwlist parameter is a NULL-terminated list of strings which identify the parameters; the names are matched with the type information from format from left to right. On success, PyArg_ParseTupleAndKeywords() returns true, otherwise it returns false and raises an appropriate exception. Note: Nested tuples cannot be parsed when using keyword arguments! Keyword parameters passed in which are not present in the kwlist will cause TypeError to be raised. Here is an example module which uses keywords, based on an example by Geoff Philbrick (philbrick@hks.com): #include "Python.h" static PyObject * keywdarg_parrot(PyObject *self, PyObject *args, PyObject *keywds) { int voltage; char *state = "a stiff"; char *action = "voom"; char *type = "Norwegian Blue"; static char *kwlist[] = {"voltage", "state", "action", "type", NULL}; if (!PyArg_ParseTupleAndKeywords(args, keywds, "i|sss", kwlist, &voltage, &state, &action, &type)) return NULL; printf("-- This parrot wouldn’t %s if you put %i Volts through it.\n", action, voltage); printf("-- Lovely plumage, the %s -- It’s %s!\n", type, state); Py_INCREF(Py_None); return Py_None; } 12

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static PyMethodDef keywdarg_methods[] = { /* The cast of the function is necessary since PyCFunction values * only take two PyObject* parameters, and keywdarg_parrot() takes * three. */ {"parrot", (PyCFunction)keywdarg_parrot, METH_VARARGS | METH_KEYWORDS, "Print a lovely skit to standard output."}, {NULL, NULL, 0, NULL} /* sentinel */ }; void initkeywdarg(void) { /* Create the module and add the functions */ Py_InitModule("keywdarg", keywdarg_methods); }

1.9 Building Arbitrary Values This function is the counterpart to PyArg_ParseTuple(). It is declared as follows: PyObject *Py_BuildValue(char *format, ...); It recognizes a set of format units similar to the ones recognized by PyArg_ParseTuple(), but the arguments (which are input to the function, not output) must not be pointers, just values. It returns a new Python object, suitable for returning from a C function called from Python. One difference with PyArg_ParseTuple(): while the latter requires its first argument to be a tuple (since Python argument lists are always represented as tuples internally), Py_BuildValue() does not always build a tuple. It builds a tuple only if its format string contains two or more format units. If the format string is empty, it returns None; if it contains exactly one format unit, it returns whatever object is described by that format unit. To force it to return a tuple of size 0 or one, parenthesize the format string. Examples (to the left the call, to the right the resulting Python value): Py_BuildValue("") Py_BuildValue("i", 123) Py_BuildValue("iii", 123, 456, 789) Py_BuildValue("s", "hello") Py_BuildValue("y", "hello") Py_BuildValue("ss", "hello", "world") Py_BuildValue("s#", "hello", 4) Py_BuildValue("y#", "hello", 4) Py_BuildValue("()") Py_BuildValue("(i)", 123) Py_BuildValue("(ii)", 123, 456) Py_BuildValue("(i,i)", 123, 456) Py_BuildValue("[i,i]", 123, 456) Py_BuildValue("{s:i,s:i}", "abc", 123, "def", 456) Py_BuildValue("((ii)(ii)) (ii)", 1, 2, 3, 4, 5, 6)

1.9. Building Arbitrary Values

None 123 (123, 456, 789) ’hello’ b’hello’ (’hello’, ’world’) ’hell’ b’hell’ () (123,) (123, 456) (123, 456) [123, 456] {’abc’: 123, ’def’: 456} (((1, 2), (3, 4)), (5, 6))

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1.10 Reference Counts In languages like C or C++, the programmer is responsible for dynamic allocation and deallocation of memory on the heap. In C, this is done using the functions malloc() and free(). In C++, the operators new and delete are used with essentially the same meaning and we’ll restrict the following discussion to the C case. Every block of memory allocated with malloc() should eventually be returned to the pool of available memory by exactly one call to free(). It is important to call free() at the right time. If a block’s address is forgotten but free() is not called for it, the memory it occupies cannot be reused until the program terminates. This is called a memory leak. On the other hand, if a program calls free() for a block and then continues to use the block, it creates a conflict with re-use of the block through another malloc() call. This is called using freed memory. It has the same bad consequences as referencing uninitialized data — core dumps, wrong results, mysterious crashes. Common causes of memory leaks are unusual paths through the code. For instance, a function may allocate a block of memory, do some calculation, and then free the block again. Now a change in the requirements for the function may add a test to the calculation that detects an error condition and can return prematurely from the function. It’s easy to forget to free the allocated memory block when taking this premature exit, especially when it is added later to the code. Such leaks, once introduced, often go undetected for a long time: the error exit is taken only in a small fraction of all calls, and most modern machines have plenty of virtual memory, so the leak only becomes apparent in a long-running process that uses the leaking function frequently. Therefore, it’s important to prevent leaks from happening by having a coding convention or strategy that minimizes this kind of errors. Since Python makes heavy use of malloc() and free(), it needs a strategy to avoid memory leaks as well as the use of freed memory. The chosen method is called reference counting. The principle is simple: every object contains a counter, which is incremented when a reference to the object is stored somewhere, and which is decremented when a reference to it is deleted. When the counter reaches zero, the last reference to the object has been deleted and the object is freed. An alternative strategy is called automatic garbage collection. (Sometimes, reference counting is also referred to as a garbage collection strategy, hence my use of “automatic” to distinguish the two.) The big advantage of automatic garbage collection is that the user doesn’t need to call free() explicitly. (Another claimed advantage is an improvement in speed or memory usage — this is no hard fact however.) The disadvantage is that for C, there is no truly portable automatic garbage collector, while reference counting can be implemented portably (as long as the functions malloc() and free() are available — which the C Standard guarantees). Maybe some day a sufficiently portable automatic garbage collector will be available for C. Until then, we’ll have to live with reference counts. While Python uses the traditional reference counting implementation, it also offers a cycle detector that works to detect reference cycles. This allows applications to not worry about creating direct or indirect circular references; these are the weakness of garbage collection implemented using only reference counting. Reference cycles consist of objects which contain (possibly indirect) references to themselves, so that each object in the cycle has a reference count which is non-zero. Typical reference counting implementations are not able to reclaim the memory belonging to any objects in a reference cycle, or referenced from the objects in the cycle, even though there are no further references to the cycle itself. The cycle detector is able to detect garbage cycles and can reclaim them so long as there are no finalizers implemented in Python (__del__() methods). When there are such finalizers, the detector exposes the cycles through the gc module (specifically, the garbage variable in that module). The gc module also exposes a way to run the detector (the collect() function), as well as configuration interfaces and the ability to disable the detector at runtime. The cycle detector is considered an optional component; though it is included by default, it can be disabled at build time using the --without-cycle-gc option to the configure script on Unix platforms (including Mac OS X). If the cycle detector is disabled in this way, the gc module will not be available.

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1.10.1 Reference Counting in Python There are two macros, Py_INCREF(x) and Py_DECREF(x), which handle the incrementing and decrementing of the reference count. Py_DECREF() also frees the object when the count reaches zero. For flexibility, it doesn’t call free() directly — rather, it makes a call through a function pointer in the object’s type object. For this purpose (and others), every object also contains a pointer to its type object. The big question now remains: when to use Py_INCREF(x) and Py_DECREF(x)? Let’s first introduce some terms. Nobody “owns” an object; however, you can own a reference to an object. An object’s reference count is now defined as the number of owned references to it. The owner of a reference is responsible for calling Py_DECREF() when the reference is no longer needed. Ownership of a reference can be transferred. There are three ways to dispose of an owned reference: pass it on, store it, or call Py_DECREF(). Forgetting to dispose of an owned reference creates a memory leak. It is also possible to borrow 2 a reference to an object. The borrower of a reference should not call Py_DECREF(). The borrower must not hold on to the object longer than the owner from which it was borrowed. Using a borrowed reference after the owner has disposed of it risks using freed memory and should be avoided completely. 3 The advantage of borrowing over owning a reference is that you don’t need to take care of disposing of the reference on all possible paths through the code — in other words, with a borrowed reference you don’t run the risk of leaking when a premature exit is taken. The disadvantage of borrowing over owning is that there are some subtle situations where in seemingly correct code a borrowed reference can be used after the owner from which it was borrowed has in fact disposed of it. A borrowed reference can be changed into an owned reference by calling Py_INCREF(). This does not affect the status of the owner from which the reference was borrowed — it creates a new owned reference, and gives full owner responsibilities (the new owner must dispose of the reference properly, as well as the previous owner).

1.10.2 Ownership Rules Whenever an object reference is passed into or out of a function, it is part of the function’s interface specification whether ownership is transferred with the reference or not. Most functions that return a reference to an object pass on ownership with the reference. In particular, all functions whose function it is to create a new object, such as PyLong_FromLong() and Py_BuildValue(), pass ownership to the receiver. Even if the object is not actually new, you still receive ownership of a new reference to that object. For instance, PyLong_FromLong() maintains a cache of popular values and can return a reference to a cached item. Many functions that extract objects from other objects also transfer ownership with the reference, for instance PyObject_GetAttrString(). The picture is less clear, here, however, since a few common routines are exceptions: PyTuple_GetItem(), PyList_GetItem(), PyDict_GetItem(), and PyDict_GetItemString() all return references that you borrow from the tuple, list or dictionary. The function PyImport_AddModule() also returns a borrowed reference, even though it may actually create the object it returns: this is possible because an owned reference to the object is stored in sys.modules. When you pass an object reference into another function, in general, the function borrows the reference from you — if it needs to store it, it will use Py_INCREF() to become an independent owner. There are exactly two important exceptions to this rule: PyTuple_SetItem() and PyList_SetItem(). These functions take over ownership of the item passed to them — even if they fail! (Note that PyDict_SetItem() and friends don’t take over ownership — they are “normal.”) 2

The metaphor of “borrowing” a reference is not completely correct: the owner still has a copy of the reference. Checking that the reference count is at least 1 does not work — the reference count itself could be in freed memory and may thus be reused for another object! 3

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When a C function is called from Python, it borrows references to its arguments from the caller. The caller owns a reference to the object, so the borrowed reference’s lifetime is guaranteed until the function returns. Only when such a borrowed reference must be stored or passed on, it must be turned into an owned reference by calling Py_INCREF(). The object reference returned from a C function that is called from Python must be an owned reference — ownership is transferred from the function to its caller.

1.10.3 Thin Ice There are a few situations where seemingly harmless use of a borrowed reference can lead to problems. These all have to do with implicit invocations of the interpreter, which can cause the owner of a reference to dispose of it. The first and most important case to know about is using Py_DECREF() on an unrelated object while borrowing a reference to a list item. For instance: void bug(PyObject *list) { PyObject *item = PyList_GetItem(list, 0); PyList_SetItem(list, 1, PyLong_FromLong(0L)); PyObject_Print(item, stdout, 0); /* BUG! */ } This function first borrows a reference to list[0], then replaces list[1] with the value 0, and finally prints the borrowed reference. Looks harmless, right? But it’s not! Let’s follow the control flow into PyList_SetItem(). The list owns references to all its items, so when item 1 is replaced, it has to dispose of the original item 1. Now let’s suppose the original item 1 was an instance of a user-defined class, and let’s further suppose that the class defined a __del__() method. If this class instance has a reference count of 1, disposing of it will call its __del__() method. Since it is written in Python, the __del__() method can execute arbitrary Python code. Could it perhaps do something to invalidate the reference to item in bug()? You bet! Assuming that the list passed into bug() is accessible to the __del__() method, it could execute a statement to the effect of del list[0], and assuming this was the last reference to that object, it would free the memory associated with it, thereby invalidating item. The solution, once you know the source of the problem, is easy: temporarily increment the reference count. The correct version of the function reads: void no_bug(PyObject *list) { PyObject *item = PyList_GetItem(list, 0); Py_INCREF(item); PyList_SetItem(list, 1, PyLong_FromLong(0L)); PyObject_Print(item, stdout, 0); Py_DECREF(item); } This is a true story. An older version of Python contained variants of this bug and someone spent a considerable amount of time in a C debugger to figure out why his __del__() methods would fail... The second case of problems with a borrowed reference is a variant involving threads. Normally, multiple threads in the Python interpreter can’t get in each other’s way, because there is a global lock protecting Python’s entire object space. However, it is possible to temporarily release this lock using the macro Py_BEGIN_ALLOW_THREADS, and to re-acquire it using Py_END_ALLOW_THREADS. This is common around blocking I/O calls, to let other threads

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use the processor while waiting for the I/O to complete. Obviously, the following function has the same problem as the previous one: void bug(PyObject *list) { PyObject *item = PyList_GetItem(list, 0); Py_BEGIN_ALLOW_THREADS ...some blocking I/O call... Py_END_ALLOW_THREADS PyObject_Print(item, stdout, 0); /* BUG! */ }

1.10.4 NULL Pointers In general, functions that take object references as arguments do not expect you to pass them NULL pointers, and will dump core (or cause later core dumps) if you do so. Functions that return object references generally return NULL only to indicate that an exception occurred. The reason for not testing for NULL arguments is that functions often pass the objects they receive on to other function — if each function were to test for NULL, there would be a lot of redundant tests and the code would run more slowly. It is better to test for NULL only at the “source:” when a pointer that may be NULL is received, for example, from malloc() or from a function that may raise an exception. The macros Py_INCREF() and Py_DECREF() do not check for NULL pointers — however, their variants Py_XINCREF() and Py_XDECREF() do. The macros for checking for a particular object type (Pytype_Check()) don’t check for NULL pointers — again, there is much code that calls several of these in a row to test an object against various different expected types, and this would generate redundant tests. There are no variants with NULL checking. The C function calling mechanism guarantees that the argument list passed to C functions (args in the examples) is never NULL — in fact it guarantees that it is always a tuple. 4 It is a severe error to ever let a NULL pointer “escape” to the Python user.

1.11 Writing Extensions in C++ It is possible to write extension modules in C++. Some restrictions apply. If the main program (the Python interpreter) is compiled and linked by the C compiler, global or static objects with constructors cannot be used. This is not a problem if the main program is linked by the C++ compiler. Functions that will be called by the Python interpreter (in particular, module initialization functions) have to be declared using extern "C". It is unnecessary to enclose the Python header files in extern "C" {...} — they use this form already if the symbol __cplusplus is defined (all recent C++ compilers define this symbol).

1.12 Providing a C API for an Extension Module Many extension modules just provide new functions and types to be used from Python, but sometimes the code in an extension module can be useful for other extension modules. For example, an extension module could implement a type “collection” which works like lists without order. Just like the standard Python list type has a C API which 4

These guarantees don’t hold when you use the “old” style calling convention — this is still found in much existing code.

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permits extension modules to create and manipulate lists, this new collection type should have a set of C functions for direct manipulation from other extension modules. At first sight this seems easy: just write the functions (without declaring them static, of course), provide an appropriate header file, and document the C API. And in fact this would work if all extension modules were always linked statically with the Python interpreter. When modules are used as shared libraries, however, the symbols defined in one module may not be visible to another module. The details of visibility depend on the operating system; some systems use one global namespace for the Python interpreter and all extension modules (Windows, for example), whereas others require an explicit list of imported symbols at module link time (AIX is one example), or offer a choice of different strategies (most Unices). And even if symbols are globally visible, the module whose functions one wishes to call might not have been loaded yet! Portability therefore requires not to make any assumptions about symbol visibility. This means that all symbols in extension modules should be declared static, except for the module’s initialization function, in order to avoid name clashes with other extension modules (as discussed in section The Module’s Method Table and Initialization Function). And it means that symbols that should be accessible from other extension modules must be exported in a different way. Python provides a special mechanism to pass C-level information (pointers) from one extension module to another one: Capsules. A Capsule is a Python data type which stores a pointer (void *). Capsules can only be created and accessed via their C API, but they can be passed around like any other Python object. In particular, they can be assigned to a name in an extension module’s namespace. Other extension modules can then import this module, retrieve the value of this name, and then retrieve the pointer from the Capsule. There are many ways in which Capsules can be used to export the C API of an extension module. Each function could get its own Capsule, or all C API pointers could be stored in an array whose address is published in a Capsule. And the various tasks of storing and retrieving the pointers can be distributed in different ways between the module providing the code and the client modules. Whichever method you choose, it’s important to name your Capsules properly. The function PyCapsule_New() takes a name parameter (const char *); you’re permitted to pass in a NULL name, but we strongly encourage you to specify a name. Properly named Capsules provide a degree of runtime type-safety; there is no feasible way to tell one unnamed Capsule from another. In particular, Capsules used to expose C APIs should be given a name following this convention: modulename.attributename The convenience function PyCapsule_Import() makes it easy to load a C API provided via a Capsule, but only if the Capsule’s name matches this convention. This behavior gives C API users a high degree of certainty that the Capsule they load contains the correct C API. The following example demonstrates an approach that puts most of the burden on the writer of the exporting module, which is appropriate for commonly used library modules. It stores all C API pointers (just one in the example!) in an array of void pointers which becomes the value of a Capsule. The header file corresponding to the module provides a macro that takes care of importing the module and retrieving its C API pointers; client modules only have to call this macro before accessing the C API. The exporting module is a modification of the spam module from section A Simple Example. The function spam.system() does not call the C library function system() directly, but a function PySpam_System(), which would of course do something more complicated in reality (such as adding “spam” to every command). This function PySpam_System() is also exported to other extension modules. The function PySpam_System() is a plain C function, declared static like everything else: static int PySpam_System(const char *command) { return system(command); }

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The function spam_system() is modified in a trivial way: static PyObject * spam_system(PyObject *self, PyObject *args) { const char *command; int sts; if (!PyArg_ParseTuple(args, "s", &command)) return NULL; sts = PySpam_System(command); return PyLong_FromLong(sts); } In the beginning of the module, right after the line #include "Python.h" two more lines must be added: #define SPAM_MODULE #include "spammodule.h" The #define is used to tell the header file that it is being included in the exporting module, not a client module. Finally, the module’s initialization function must take care of initializing the C API pointer array: PyMODINIT_FUNC PyInit_spam(void) { PyObject *m; static void *PySpam_API[PySpam_API_pointers]; PyObject *c_api_object; m = PyModule_Create(&spammodule); if (m == NULL) return NULL; /* Initialize the C API pointer array */ PySpam_API[PySpam_System_NUM] = (void *)PySpam_System; /* Create a Capsule containing the API pointer array’s address */ c_api_object = PyCapsule_New((void *)PySpam_API, "spam._C_API", NULL); if (c_api_object != NULL) PyModule_AddObject(m, "_C_API", c_api_object); return m; } Note that PySpam_API is declared static; otherwise the pointer array would disappear when PyInit_spam() terminates! The bulk of the work is in the header file spammodule.h, which looks like this: #ifndef Py_SPAMMODULE_H #define Py_SPAMMODULE_H #ifdef __cplusplus extern "C" { #endif

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/* Header file for spammodule */ /* C API functions */ #define PySpam_System_NUM 0 #define PySpam_System_RETURN int #define PySpam_System_PROTO (const char *command) /* Total number of C API pointers */ #define PySpam_API_pointers 1

#ifdef SPAM_MODULE /* This section is used when compiling spammodule.c */ static PySpam_System_RETURN PySpam_System PySpam_System_PROTO; #else /* This section is used in modules that use spammodule’s API */ static void **PySpam_API; #define PySpam_System \ (*(PySpam_System_RETURN (*)PySpam_System_PROTO) PySpam_API[PySpam_System_NUM]) /* Return -1 on error, 0 on success. * PyCapsule_Import will set an exception if there’s an error. */ static int import_spam(void) { PySpam_API = (void **)PyCapsule_Import("spam._C_API", 0); return (PySpam_API != NULL) ? 0 : -1; } #endif #ifdef __cplusplus } #endif #endif /* !defined(Py_SPAMMODULE_H) */ All that a client module must do in order to have access to the function PySpam_System() is to call the function (or rather macro) import_spam() in its initialization function: PyMODINIT_FUNC PyInit_client(void) { PyObject *m; m = PyModule_Create(&clientmodule); if (m == NULL) return NULL; if (import_spam() < 0) return NULL;

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/* additional initialization can happen here */ return m; } The main disadvantage of this approach is that the file spammodule.h is rather complicated. However, the basic structure is the same for each function that is exported, so it has to be learned only once. Finally it should be mentioned that Capsules offer additional functionality, which is especially useful for memory allocation and deallocation of the pointer stored in a Capsule. The details are described in the Python/C API Reference Manual in the section Capsules (in The Python/C API) and in the implementation of Capsules (files Include/pycapsule.h and Objects/pycapsule.c in the Python source code distribution).

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CHAPTER

TWO

DEFINING NEW TYPES As mentioned in the last chapter, Python allows the writer of an extension module to define new types that can be manipulated from Python code, much like strings and lists in core Python. This is not hard; the code for all extension types follows a pattern, but there are some details that you need to understand before you can get started.

2.1 The Basics The Python runtime sees all Python objects as variables of type PyObject*. A PyObject is not a very magnificent object - it just contains the refcount and a pointer to the object’s “type object”. This is where the action is; the type object determines which (C) functions get called when, for instance, an attribute gets looked up on an object or it is multiplied by another object. These C functions are called “type methods” to distinguish them from things like [].append (which we call “object methods”). So, if you want to define a new object type, you need to create a new type object. This sort of thing can only be explained by example, so here’s a minimal, but complete, module that defines a new type: #include <Python.h> typedef struct { PyObject_HEAD /* Type-specific fields go here. */ } noddy_NoddyObject; static PyTypeObject noddy_NoddyType = { PyVarObject_HEAD_INIT(NULL, 0) "noddy.Noddy", /* tp_name */ sizeof(noddy_NoddyObject), /* tp_basicsize */ 0, /* tp_itemsize */ 0, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_reserved */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */

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0, 0, 0, 0, 0, 0, Py_TPFLAGS_DEFAULT, "Noddy objects",

/* /* /* /* /* /* /* /*

tp_hash */ tp_call */ tp_str */ tp_getattro */ tp_setattro */ tp_as_buffer */ tp_flags */ tp_doc */

}; static PyModuleDef noddymodule = { PyModuleDef_HEAD_INIT, "noddy", "Example module that creates an extension type.", -1, NULL, NULL, NULL, NULL, NULL }; PyMODINIT_FUNC PyInit_noddy(void) { PyObject* m; noddy_NoddyType.tp_new = PyType_GenericNew; if (PyType_Ready(&noddy_NoddyType) < 0) return NULL; m = PyModule_Create(&noddymodule); if (m == NULL) return NULL; Py_INCREF(&noddy_NoddyType); PyModule_AddObject(m, "Noddy", (PyObject *)&noddy_NoddyType); return m; } Now that’s quite a bit to take in at once, but hopefully bits will seem familiar from the last chapter. The first bit that will be new is: typedef struct { PyObject_HEAD } noddy_NoddyObject; This is what a Noddy object will contain—in this case, nothing more than every Python object contains, namely a refcount and a pointer to a type object. These are the fields the PyObject_HEAD macro brings in. The reason for the macro is to standardize the layout and to enable special debugging fields in debug builds. Note that there is no semicolon after the PyObject_HEAD macro; one is included in the macro definition. Be wary of adding one by accident; it’s easy to do from habit, and your compiler might not complain, but someone else’s probably will! (On Windows, MSVC is known to call this an error and refuse to compile the code.) For contrast, let’s take a look at the corresponding definition for standard Python floats: typedef struct { PyObject_HEAD double ob_fval; } PyFloatObject;

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Moving on, we come to the crunch — the type object. static PyTypeObject noddy_NoddyType = { PyVarObject_HEAD_INIT(NULL, 0) "noddy.Noddy", /* tp_name */ sizeof(noddy_NoddyObject), /* tp_basicsize */ 0, /* tp_itemsize */ 0, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_reserved */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT, /* tp_flags */ "Noddy objects", /* tp_doc */ }; Now if you go and look up the definition of PyTypeObject in object.h you’ll see that it has many more fields that the definition above. The remaining fields will be filled with zeros by the C compiler, and it’s common practice to not specify them explicitly unless you need them. This is so important that we’re going to pick the top of it apart still further: PyVarObject_HEAD_INIT(NULL, 0) This line is a bit of a wart; what we’d like to write is: PyVarObject_HEAD_INIT(&PyType_Type, 0) as the type of a type object is “type”, but this isn’t strictly conforming C and some compilers complain. Fortunately, this member will be filled in for us by PyType_Ready(). "noddy.Noddy",

/* tp_name */

The name of our type. This will appear in the default textual representation of our objects and in some error messages, for example: >>> "" + noddy.new_noddy() Traceback (most recent call last): File "<stdin>", line 1, in ? TypeError: cannot add type "noddy.Noddy" to string Note that the name is a dotted name that includes both the module name and the name of the type within the module. The module in this case is noddy and the type is Noddy, so we set the type name to noddy.Noddy. sizeof(noddy_NoddyObject),

/* tp_basicsize */

This is so that Python knows how much memory to allocate when you call PyObject_New(). Note: If you want your type to be subclassable from Python, and your type has the same tp_basicsize as its base type, you may have problems with multiple inheritance. A Python subclass of your type will have to list your type first in its __bases__, or else it will not be able to call your type’s __new__() method without getting an error.

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You can avoid this problem by ensuring that your type has a larger value for tp_basicsize than its base type does. Most of the time, this will be true anyway, because either your base type will be object, or else you will be adding data members to your base type, and therefore increasing its size. 0,

/* tp_itemsize */

This has to do with variable length objects like lists and strings. Ignore this for now. Skipping a number of type methods that we don’t provide, we set the class flags to Py_TPFLAGS_DEFAULT. Py_TPFLAGS_DEFAULT,

/* tp_flags */

All types should include this constant in their flags. It enables all of the members defined by the current version of Python. We provide a doc string for the type in tp_doc. "Noddy objects",

/* tp_doc */

Now we get into the type methods, the things that make your objects different from the others. We aren’t going to implement any of these in this version of the module. We’ll expand this example later to have more interesting behavior. For now, all we want to be able to do is to create new Noddy objects. To enable object creation, we have to provide a tp_new implementation. In this case, we can just use the default implementation provided by the API function PyType_GenericNew(). We’d like to just assign this to the tp_new slot, but we can’t, for portability sake, On some platforms or compilers, we can’t statically initialize a structure member with a function defined in another C module, so, instead, we’ll assign the tp_new slot in the module initialization function just before calling PyType_Ready(): noddy_NoddyType.tp_new = PyType_GenericNew; if (PyType_Ready(&noddy_NoddyType) < 0) return; All the other type methods are NULL, so we’ll go over them later — that’s for a later section! Everything else in the file should be familiar, except for some code in PyInit_noddy(): if (PyType_Ready(&noddy_NoddyType) < 0) return; This initializes the Noddy type, filing in a number of members, including ob_type that we initially set to NULL. PyModule_AddObject(m, "Noddy", (PyObject *)&noddy_NoddyType); This adds the type to the module dictionary. This allows us to create Noddy instances by calling the Noddy class: >>> import noddy >>> mynoddy = noddy.Noddy() That’s it! All that remains is to build it; put the above code in a file called noddy.c and from distutils.core import setup, Extension setup(name="noddy", version="1.0", ext_modules=[Extension("noddy", ["noddy.c"])]) in a file called setup.py; then typing $ python setup.py build at a shell should produce a file noddy.so in a subdirectory; move to that directory and fire up Python — you should be able to import noddy and play around with Noddy objects. That wasn’t so hard, was it?

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Of course, the current Noddy type is pretty uninteresting. It has no data and doesn’t do anything. It can’t even be subclassed.

2.1.1 Adding data and methods to the Basic example Let’s expend the basic example to add some data and methods. Let’s also make the type usable as a base class. We’ll create a new module, noddy2 that adds these capabilities: #include <Python.h> #include "structmember.h" typedef struct { PyObject_HEAD PyObject *first; /* first name */ PyObject *last; /* last name */ int number; } Noddy; static void Noddy_dealloc(Noddy* self) { Py_XDECREF(self->first); Py_XDECREF(self->last); Py_TYPE(self)->tp_free((PyObject*)self); } static PyObject * Noddy_new(PyTypeObject *type, PyObject *args, PyObject *kwds) { Noddy *self; self = (Noddy *)type->tp_alloc(type, 0); if (self != NULL) { self->first = PyUnicode_FromString(""); if (self->first == NULL) { Py_DECREF(self); return NULL; } self->last = PyUnicode_FromString(""); if (self->last == NULL) { Py_DECREF(self); return NULL; } self->number = 0; } return (PyObject *)self; } static int 2.1. The Basics

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Noddy_init(Noddy *self, PyObject *args, PyObject *kwds) { PyObject *first=NULL, *last=NULL, *tmp; static char *kwlist[] = {"first", "last", "number", NULL}; if (! PyArg_ParseTupleAndKeywords(args, kwds, "|OOi", kwlist, &first, &last, &self->number)) return -1; if (first) { tmp = self->first; Py_INCREF(first); self->first = first; Py_XDECREF(tmp); } if (last) { tmp = self->last; Py_INCREF(last); self->last = last; Py_XDECREF(tmp); } return 0; }

static PyMemberDef Noddy_members[] = { {"first", T_OBJECT_EX, offsetof(Noddy, first), 0, "first name"}, {"last", T_OBJECT_EX, offsetof(Noddy, last), 0, "last name"}, {"number", T_INT, offsetof(Noddy, number), 0, "noddy number"}, {NULL} /* Sentinel */ }; static PyObject * Noddy_name(Noddy* self) { static PyObject *format = NULL; PyObject *args, *result; if (format == NULL) { format = PyUnicode_FromString("%s %s"); if (format == NULL) return NULL; } if (self->first == NULL) { PyErr_SetString(PyExc_AttributeError, "first"); return NULL;

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} if (self->last == NULL) { PyErr_SetString(PyExc_AttributeError, "last"); return NULL; } args = Py_BuildValue("OO", self->first, self->last); if (args == NULL) return NULL; result = PyUnicode_Format(format, args); Py_DECREF(args); return result; } static PyMethodDef Noddy_methods[] = { {"name", (PyCFunction)Noddy_name, METH_NOARGS, "Return the name, combining the first and last name" }, {NULL} /* Sentinel */ }; static PyTypeObject NoddyType = { PyVarObject_HEAD_INIT(NULL, 0) "noddy.Noddy", /* tp_name */ sizeof(Noddy), /* tp_basicsize */ 0, /* tp_itemsize */ (destructor)Noddy_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_reserved */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, /* tp_flags */ "Noddy objects", /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ Noddy_methods, /* tp_methods */ 2.1. The Basics

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Noddy_members, 0, 0, 0, 0, 0, 0, (initproc)Noddy_init, 0, Noddy_new,

/* /* /* /* /* /* /* /* /* /*

tp_members */ tp_getset */ tp_base */ tp_dict */ tp_descr_get */ tp_descr_set */ tp_dictoffset */ tp_init */ tp_alloc */ tp_new */

}; static PyModuleDef noddy2module = { PyModuleDef_HEAD_INIT, "noddy2", "Example module that creates an extension type.", -1, NULL, NULL, NULL, NULL, NULL }; PyMODINIT_FUNC PyInit_noddy2(void) { PyObject* m; if (PyType_Ready(&NoddyType) < 0) return NULL; m = PyModule_Create(&noddy2module); if (m == NULL) return NULL; Py_INCREF(&NoddyType); PyModule_AddObject(m, "Noddy", (PyObject *)&NoddyType); return m; } This version of the module has a number of changes. We’ve added an extra include: #include <structmember.h> This include provides declarations that we use to handle attributes, as described a bit later. The name of the Noddy object structure has been shortened to Noddy. The type object name has been shortened to NoddyType. The Noddy type now has three data attributes, first, last, and number. The first and last variables are Python strings containing first and last names. The number attribute is an integer. The object structure is updated accordingly: typedef struct { PyObject_HEAD PyObject *first; PyObject *last;

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int number; } Noddy; Because we now have data to manage, we have to be more careful about object allocation and deallocation. At a minimum, we need a deallocation method: static void Noddy_dealloc(Noddy* self) { Py_XDECREF(self->first); Py_XDECREF(self->last); Py_TYPE(self)->tp_free((PyObject*)self); } which is assigned to the tp_dealloc member: (destructor)Noddy_dealloc, /*tp_dealloc*/ This method decrements the reference counts of the two Python attributes. We use Py_XDECREF() here because the first and last members could be NULL. It then calls the tp_free member of the object’s type to free the object’s memory. Note that the object’s type might not be NoddyType, because the object may be an instance of a subclass. We want to make sure that the first and last names are initialized to empty strings, so we provide a new method: static PyObject * Noddy_new(PyTypeObject *type, PyObject *args, PyObject *kwds) { Noddy *self; self = (Noddy *)type->tp_alloc(type, 0); if (self != NULL) { self->first = PyString_FromString(""); if (self->first == NULL) { Py_DECREF(self); return NULL; } self->last = PyString_FromString(""); if (self->last == NULL) { Py_DECREF(self); return NULL; } self->number = 0; } return (PyObject *)self; } and install it in the tp_new member: Noddy_new,

/* tp_new */

The new member is responsible for creating (as opposed to initializing) objects of the type. It is exposed in Python as the __new__() method. See the paper titled “Unifying types and classes in Python” for a detailed discussion of the __new__() method. One reason to implement a new method is to assure the initial values of instance variables. In

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this case, we use the new method to make sure that the initial values of the members first and last are not NULL. If we didn’t care whether the initial values were NULL, we could have used PyType_GenericNew() as our new method, as we did before. PyType_GenericNew() initializes all of the instance variable members to NULL. The new method is a static method that is passed the type being instantiated and any arguments passed when the type was called, and that returns the new object created. New methods always accept positional and keyword arguments, but they often ignore the arguments, leaving the argument handling to initializer methods. Note that if the type supports subclassing, the type passed may not be the type being defined. The new method calls the tp_alloc slot to allocate memory. We don’t fill the tp_alloc slot ourselves. Rather PyType_Ready() fills it for us by inheriting it from our base class, which is object by default. Most types use the default allocation. Note: If you are creating a co-operative tp_new (one that calls a base type’s tp_new or __new__()), you must not try to determine what method to call using method resolution order at runtime. Always statically determine what type you are going to call, and call its tp_new directly, or via type->tp_base->tp_new. If you do not do this, Python subclasses of your type that also inherit from other Python-defined classes may not work correctly. (Specifically, you may not be able to create instances of such subclasses without getting a TypeError.) We provide an initialization function: static int Noddy_init(Noddy *self, PyObject *args, PyObject *kwds) { PyObject *first=NULL, *last=NULL, *tmp; static char *kwlist[] = {"first", "last", "number", NULL}; if (! PyArg_ParseTupleAndKeywords(args, kwds, "|OOi", kwlist, &first, &last, &self->number)) return -1; if (first) { tmp = self->first; Py_INCREF(first); self->first = first; Py_XDECREF(tmp); } if (last) { tmp = self->last; Py_INCREF(last); self->last = last; Py_XDECREF(tmp); } return 0; } by filling the tp_init slot. (initproc)Noddy_init,

/* tp_init */

The tp_init slot is exposed in Python as the __init__() method. It is used to initialize an object after it’s created. Unlike the new method, we can’t guarantee that the initializer is called. The initializer isn’t called when unpickling objects and it can be overridden. Our initializer accepts arguments to provide initial values for our instance. Initializers always accept positional and keyword arguments.

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Initializers can be called multiple times. Anyone can call the __init__() method on our objects. For this reason, we have to be extra careful when assigning the new values. We might be tempted, for example to assign the first member like this: if (first) { Py_XDECREF(self->first); Py_INCREF(first); self->first = first; } But this would be risky. Our type doesn’t restrict the type of the first member, so it could be any kind of object. It could have a destructor that causes code to be executed that tries to access the first member. To be paranoid and protect ourselves against this possibility, we almost always reassign members before decrementing their reference counts. When don’t we have to do this? • when we absolutely know that the reference count is greater than 1 • when we know that deallocation of the object 1 will not cause any calls back into our type’s code • when decrementing a reference count in a tp_dealloc handler when garbage-collections is not supported 2 We want to expose our instance variables as attributes. There are a number of ways to do that. The simplest way is to define member definitions: static PyMemberDef Noddy_members[] = { {"first", T_OBJECT_EX, offsetof(Noddy, first), 0, "first name"}, {"last", T_OBJECT_EX, offsetof(Noddy, last), 0, "last name"}, {"number", T_INT, offsetof(Noddy, number), 0, "noddy number"}, {NULL} /* Sentinel */ }; and put the definitions in the tp_members slot: Noddy_members,

/* tp_members */

Each member definition has a member name, type, offset, access flags and documentation string. See the Generic Attribute Management section below for details. A disadvantage of this approach is that it doesn’t provide a way to restrict the types of objects that can be assigned to the Python attributes. We expect the first and last names to be strings, but any Python objects can be assigned. Further, the attributes can be deleted, setting the C pointers to NULL. Even though we can make sure the members are initialized to non-NULL values, the members can be set to NULL if the attributes are deleted. We define a single method, name(), that outputs the objects name as the concatenation of the first and last names. static PyObject * Noddy_name(Noddy* self) { static PyObject *format = NULL; PyObject *args, *result; if (format == NULL) { format = PyString_FromString("%s %s"); 1

This is true when we know that the object is a basic type, like a string or a float. We relied on this in the tp_dealloc handler in this example, because our type doesn’t support garbage collection. Even if a type supports garbage collection, there are calls that can be made to “untrack” the object from garbage collection, however, these calls are advanced and not covered here. 2

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if (format == NULL) return NULL; } if (self->first == NULL) { PyErr_SetString(PyExc_AttributeError, "first"); return NULL; } if (self->last == NULL) { PyErr_SetString(PyExc_AttributeError, "last"); return NULL; } args = Py_BuildValue("OO", self->first, self->last); if (args == NULL) return NULL; result = PyString_Format(format, args); Py_DECREF(args); return result; } The method is implemented as a C function that takes a Noddy (or Noddy subclass) instance as the first argument. Methods always take an instance as the first argument. Methods often take positional and keyword arguments as well, but in this cased we don’t take any and don’t need to accept a positional argument tuple or keyword argument dictionary. This method is equivalent to the Python method: def name(self): return "%s %s" % (self.first, self.last) Note that we have to check for the possibility that our first and last members are NULL. This is because they can be deleted, in which case they are set to NULL. It would be better to prevent deletion of these attributes and to restrict the attribute values to be strings. We’ll see how to do that in the next section. Now that we’ve defined the method, we need to create an array of method definitions: static PyMethodDef Noddy_methods[] = { {"name", (PyCFunction)Noddy_name, METH_NOARGS, "Return the name, combining the first and last name" }, {NULL} /* Sentinel */ }; and assign them to the tp_methods slot: Noddy_methods,

/* tp_methods */

Note that we used the METH_NOARGS flag to indicate that the method is passed no arguments. Finally, we’ll make our type usable as a base class. We’ve written our methods carefully so far so that they don’t make any assumptions about the type of the object being created or used, so all we need to do is to add the Py_TPFLAGS_BASETYPE to our class flag definition: Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, /*tp_flags*/ We rename PyInit_noddy() to PyInit_noddy2() and update the module name in the PyModuleDef struct. Finally, we update our setup.py file to build the new module:

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from distutils.core import setup, Extension setup(name="noddy", version="1.0", ext_modules=[ Extension("noddy", ["noddy.c"]), Extension("noddy2", ["noddy2.c"]), ])

2.1.2 Providing finer control over data attributes In this section, we’ll provide finer control over how the first and last attributes are set in the Noddy example. In the previous version of our module, the instance variables first and last could be set to non-string values or even deleted. We want to make sure that these attributes always contain strings. #include <Python.h> #include "structmember.h" typedef struct { PyObject_HEAD PyObject *first; PyObject *last; int number; } Noddy; static void Noddy_dealloc(Noddy* self) { Py_XDECREF(self->first); Py_XDECREF(self->last); Py_TYPE(self)->tp_free((PyObject*)self); } static PyObject * Noddy_new(PyTypeObject *type, PyObject *args, PyObject *kwds) { Noddy *self; self = (Noddy *)type->tp_alloc(type, 0); if (self != NULL) { self->first = PyUnicode_FromString(""); if (self->first == NULL) { Py_DECREF(self); return NULL; } self->last = PyUnicode_FromString(""); if (self->last == NULL) { Py_DECREF(self); return NULL; } self->number = 0; } 2.1. The Basics

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return (PyObject *)self; } static int Noddy_init(Noddy *self, PyObject *args, PyObject *kwds) { PyObject *first=NULL, *last=NULL, *tmp; static char *kwlist[] = {"first", "last", "number", NULL}; if (! PyArg_ParseTupleAndKeywords(args, kwds, "|SSi", kwlist, &first, &last, &self->number)) return -1; if (first) { tmp = self->first; Py_INCREF(first); self->first = first; Py_DECREF(tmp); } if (last) { tmp = self->last; Py_INCREF(last); self->last = last; Py_DECREF(tmp); } return 0; } static PyMemberDef Noddy_members[] = { {"number", T_INT, offsetof(Noddy, number), 0, "noddy number"}, {NULL} /* Sentinel */ }; static PyObject * Noddy_getfirst(Noddy *self, void *closure) { Py_INCREF(self->first); return self->first; } static int Noddy_setfirst(Noddy *self, PyObject *value, void *closure) { if (value == NULL) { PyErr_SetString(PyExc_TypeError, "Cannot delete the first attribute"); return -1; }

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if (! PyUnicode_Check(value)) { PyErr_SetString(PyExc_TypeError, "The first attribute value must be a string"); return -1; } Py_DECREF(self->first); Py_INCREF(value); self->first = value; return 0; } static PyObject * Noddy_getlast(Noddy *self, void *closure) { Py_INCREF(self->last); return self->last; } static int Noddy_setlast(Noddy *self, PyObject *value, void *closure) { if (value == NULL) { PyErr_SetString(PyExc_TypeError, "Cannot delete the last attribute"); return -1; } if (! PyUnicode_Check(value)) { PyErr_SetString(PyExc_TypeError, "The last attribute value must be a string"); return -1; } Py_DECREF(self->last); Py_INCREF(value); self->last = value; return 0; } static PyGetSetDef Noddy_getseters[] = { {"first", (getter)Noddy_getfirst, (setter)Noddy_setfirst, "first name", NULL}, {"last", (getter)Noddy_getlast, (setter)Noddy_setlast, "last name", NULL}, {NULL} /* Sentinel */ }; static PyObject * 2.1. The Basics

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Noddy_name(Noddy* self) { static PyObject *format = NULL; PyObject *args, *result; if (format == NULL) { format = PyUnicode_FromString("%s %s"); if (format == NULL) return NULL; } args = Py_BuildValue("OO", self->first, self->last); if (args == NULL) return NULL; result = PyUnicode_Format(format, args); Py_DECREF(args); return result; } static PyMethodDef Noddy_methods[] = { {"name", (PyCFunction)Noddy_name, METH_NOARGS, "Return the name, combining the first and last name" }, {NULL} /* Sentinel */ }; static PyTypeObject NoddyType = { PyVarObject_HEAD_INIT(NULL, 0) "noddy.Noddy", /* tp_name */ sizeof(Noddy), /* tp_basicsize */ 0, /* tp_itemsize */ (destructor)Noddy_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_reserved */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, /* tp_flags */ "Noddy objects", /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 38

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0, 0, 0, Noddy_methods, Noddy_members, Noddy_getseters, 0, 0, 0, 0, 0, (initproc)Noddy_init, 0, Noddy_new,

/* /* /* /* /* /* /* /* /* /* /*

/* tp_weaklistoffset */ /* tp_iter */ /* tp_iternext */ tp_methods */ tp_members */ tp_getset */ tp_base */ tp_dict */ tp_descr_get */ tp_descr_set */ tp_dictoffset */ tp_init */ tp_alloc */ tp_new */

}; static PyModuleDef noddy3module = { PyModuleDef_HEAD_INIT, "noddy3", "Example module that creates an extension type.", -1, NULL, NULL, NULL, NULL, NULL }; PyMODINIT_FUNC PyInit_noddy3(void) { PyObject* m; if (PyType_Ready(&NoddyType) < 0) return NULL; m = PyModule_Create(&noddy3module); if (m == NULL) return NULL; Py_INCREF(&NoddyType); PyModule_AddObject(m, "Noddy", (PyObject *)&NoddyType); return m; } To provide greater control, over the first and last attributes, we’ll use custom getter and setter functions. Here are the functions for getting and setting the first attribute: Noddy_getfirst(Noddy *self, void *closure) { Py_INCREF(self->first); return self->first; } static int Noddy_setfirst(Noddy *self, PyObject *value, void *closure) { if (value == NULL) { PyErr_SetString(PyExc_TypeError, "Cannot delete the first attribute");

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return -1; } if (! PyString_Check(value)) { PyErr_SetString(PyExc_TypeError, "The first attribute value must be a string"); return -1; } Py_DECREF(self->first); Py_INCREF(value); self->first = value; return 0; } The getter function is passed a Noddy object and a “closure”, which is void pointer. In this case, the closure is ignored. (The closure supports an advanced usage in which definition data is passed to the getter and setter. This could, for example, be used to allow a single set of getter and setter functions that decide the attribute to get or set based on data in the closure.) The setter function is passed the Noddy object, the new value, and the closure. The new value may be NULL, in which case the attribute is being deleted. In our setter, we raise an error if the attribute is deleted or if the attribute value is not a string. We create an array of PyGetSetDef structures: static PyGetSetDef Noddy_getseters[] = { {"first", (getter)Noddy_getfirst, (setter)Noddy_setfirst, "first name", NULL}, {"last", (getter)Noddy_getlast, (setter)Noddy_setlast, "last name", NULL}, {NULL} /* Sentinel */ }; and register it in the tp_getset slot: Noddy_getseters,

/* tp_getset */

to register our attribute getters and setters. The last item in a PyGetSetDef structure is the closure mentioned above. In this case, we aren’t using the closure, so we just pass NULL. We also remove the member definitions for these attributes: static PyMemberDef Noddy_members[] = { {"number", T_INT, offsetof(Noddy, number), 0, "noddy number"}, {NULL} /* Sentinel */ }; We also need to update the tp_init handler to only allow strings 3 to be passed: 3 We now know that the first and last members are strings, so perhaps we could be less careful about decrementing their reference counts, however, we accept instances of string subclasses. Even though deallocating normal strings won’t call back into our objects, we can’t guarantee that

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static int Noddy_init(Noddy *self, PyObject *args, PyObject *kwds) { PyObject *first=NULL, *last=NULL, *tmp; static char *kwlist[] = {"first", "last", "number", NULL}; if (! PyArg_ParseTupleAndKeywords(args, kwds, "|SSi", kwlist, &first, &last, &self->number)) return -1; if (first) { tmp = self->first; Py_INCREF(first); self->first = first; Py_DECREF(tmp); } if (last) { tmp = self->last; Py_INCREF(last); self->last = last; Py_DECREF(tmp); } return 0; } With these changes, we can assure that the first and last members are never NULL so we can remove checks for NULL values in almost all cases. This means that most of the Py_XDECREF() calls can be converted to Py_DECREF() calls. The only place we can’t change these calls is in the deallocator, where there is the possibility that the initialization of these members failed in the constructor. We also rename the module initialization function and module name in the initialization function, as we did before, and we add an extra definition to the setup.py file.

2.1.3 Supporting cyclic garbage collection Python has a cyclic-garbage collector that can identify unneeded objects even when their reference counts are not zero. This can happen when objects are involved in cycles. For example, consider: >>> l = [] >>> l.append(l) >>> del l In this example, we create a list that contains itself. When we delete it, it still has a reference from itself. Its reference count doesn’t drop to zero. Fortunately, Python’s cyclic-garbage collector will eventually figure out that the list is garbage and free it. In the second version of the Noddy example, we allowed any kind of object to be stored in the first or last attributes. 4 This means that Noddy objects can participate in cycles: deallocating an instance of a string subclass won’t call back into our objects. 4 Even in the third version, we aren’t guaranteed to avoid cycles. Instances of string subclasses are allowed and string subclasses could allow cycles even if normal strings don’t.

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>>> >>> >>> >>>

import noddy2 n = noddy2.Noddy() l = [n] n.first = l

This is pretty silly, but it gives us an excuse to add support for the cyclic-garbage collector to the Noddy example. To support cyclic garbage collection, types need to fill two slots and set a class flag that enables these slots: #include <Python.h> #include "structmember.h" typedef struct { PyObject_HEAD PyObject *first; PyObject *last; int number; } Noddy; static int Noddy_traverse(Noddy *self, visitproc visit, void *arg) { int vret; if (self->first) { vret = visit(self->first, arg); if (vret != 0) return vret; } if (self->last) { vret = visit(self->last, arg); if (vret != 0) return vret; } return 0; } static int Noddy_clear(Noddy *self) { PyObject *tmp; tmp = self->first; self->first = NULL; Py_XDECREF(tmp); tmp = self->last; self->last = NULL; Py_XDECREF(tmp); return 0; } static void Noddy_dealloc(Noddy* self) 42

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{ Noddy_clear(self); Py_TYPE(self)->tp_free((PyObject*)self); } static PyObject * Noddy_new(PyTypeObject *type, PyObject *args, PyObject *kwds) { Noddy *self; self = (Noddy *)type->tp_alloc(type, 0); if (self != NULL) { self->first = PyUnicode_FromString(""); if (self->first == NULL) { Py_DECREF(self); return NULL; } self->last = PyUnicode_FromString(""); if (self->last == NULL) { Py_DECREF(self); return NULL; } self->number = 0; } return (PyObject *)self; } static int Noddy_init(Noddy *self, PyObject *args, PyObject *kwds) { PyObject *first=NULL, *last=NULL, *tmp; static char *kwlist[] = {"first", "last", "number", NULL}; if (! PyArg_ParseTupleAndKeywords(args, kwds, "|OOi", kwlist, &first, &last, &self->number)) return -1; if (first) { tmp = self->first; Py_INCREF(first); self->first = first; Py_XDECREF(tmp); } if (last) { tmp = self->last; Py_INCREF(last);

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self->last = last; Py_XDECREF(tmp); } return 0; }

static PyMemberDef Noddy_members[] = { {"first", T_OBJECT_EX, offsetof(Noddy, first), 0, "first name"}, {"last", T_OBJECT_EX, offsetof(Noddy, last), 0, "last name"}, {"number", T_INT, offsetof(Noddy, number), 0, "noddy number"}, {NULL} /* Sentinel */ }; static PyObject * Noddy_name(Noddy* self) { static PyObject *format = NULL; PyObject *args, *result; if (format == NULL) { format = PyUnicode_FromString("%s %s"); if (format == NULL) return NULL; } if (self->first == NULL) { PyErr_SetString(PyExc_AttributeError, "first"); return NULL; } if (self->last == NULL) { PyErr_SetString(PyExc_AttributeError, "last"); return NULL; } args = Py_BuildValue("OO", self->first, self->last); if (args == NULL) return NULL; result = PyUnicode_Format(format, args); Py_DECREF(args); return result; } static PyMethodDef Noddy_methods[] = { {"name", (PyCFunction)Noddy_name, METH_NOARGS, "Return the name, combining the first and last name" },

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{NULL}

/* Sentinel */

}; static PyTypeObject NoddyType = { PyVarObject_HEAD_INIT(NULL, 0) "noddy.Noddy", /* tp_name */ sizeof(Noddy), /* tp_basicsize */ 0, /* tp_itemsize */ (destructor)Noddy_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_reserved */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE | Py_TPFLAGS_HAVE_GC, /* tp_flags */ "Noddy objects", /* tp_doc */ (traverseproc)Noddy_traverse, /* tp_traverse */ (inquiry)Noddy_clear, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ Noddy_methods, /* tp_methods */ Noddy_members, /* tp_members */ 0, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ 0, /* tp_descr_get */ 0, /* tp_descr_set */ 0, /* tp_dictoffset */ (initproc)Noddy_init, /* tp_init */ 0, /* tp_alloc */ Noddy_new, /* tp_new */ }; static PyModuleDef noddy4module = { PyModuleDef_HEAD_INIT, "noddy4", "Example module that creates an extension type.", -1, NULL, NULL, NULL, NULL, NULL };

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PyMODINIT_FUNC PyInit_noddy4(void) { PyObject* m; if (PyType_Ready(&NoddyType) < 0) return NULL; m = PyModule_Create(&noddy4module); if (m == NULL) return NULL; Py_INCREF(&NoddyType); PyModule_AddObject(m, "Noddy", (PyObject *)&NoddyType); return m; } The traversal method provides access to subobjects that could participate in cycles: static int Noddy_traverse(Noddy *self, visitproc visit, void *arg) { int vret; if (self->first) { vret = visit(self->first, arg); if (vret != 0) return vret; } if (self->last) { vret = visit(self->last, arg); if (vret != 0) return vret; } return 0; } For each subobject that can participate in cycles, we need to call the visit() function, which is passed to the traversal method. The visit() function takes as arguments the subobject and the extra argument arg passed to the traversal method. It returns an integer value that must be returned if it is non-zero. Python provides a Py_VISIT() macro that automates calling visit functions. Noddy_traverse() can be simplified:

With Py_VISIT(),

static int Noddy_traverse(Noddy *self, visitproc visit, void *arg) { Py_VISIT(self->first); Py_VISIT(self->last); return 0; } Note: Note that the tp_traverse implementation must name its arguments exactly visit and arg in order to use Py_VISIT(). This is to encourage uniformity across these boring implementations.

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We also need to provide a method for clearing any subobjects that can participate in cycles. We implement the method and reimplement the deallocator to use it: static int Noddy_clear(Noddy *self) { PyObject *tmp; tmp = self->first; self->first = NULL; Py_XDECREF(tmp); tmp = self->last; self->last = NULL; Py_XDECREF(tmp); return 0; } static void Noddy_dealloc(Noddy* self) { Noddy_clear(self); Py_TYPE(self)->tp_free((PyObject*)self); } Notice the use of a temporary variable in Noddy_clear(). We use the temporary variable so that we can set each member to NULL before decrementing its reference count. We do this because, as was discussed earlier, if the reference count drops to zero, we might cause code to run that calls back into the object. In addition, because we now support garbage collection, we also have to worry about code being run that triggers garbage collection. If garbage collection is run, our tp_traverse handler could get called. We can’t take a chance of having Noddy_traverse() called when a member’s reference count has dropped to zero and its value hasn’t been set to NULL. Python provides a Py_CLEAR() that automates the careful decrementing of reference counts. With Py_CLEAR(), the Noddy_clear() function can be simplified: static int Noddy_clear(Noddy *self) { Py_CLEAR(self->first); Py_CLEAR(self->last); return 0; } Finally, we add the Py_TPFLAGS_HAVE_GC flag to the class flags: Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE | Py_TPFLAGS_HAVE_GC, /* tp_flags */ That’s pretty much it. If we had written custom tp_alloc or tp_free slots, we’d need to modify them for cyclicgarbage collection. Most extensions will use the versions automatically provided.

2.1.4 Subclassing other types It is possible to create new extension types that are derived from existing types. It is easiest to inherit from the built in types, since an extension can easily use the PyTypeObject it needs. It can be difficult to share these PyTypeObject structures between extension modules.

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In this example we will create a Shoddy type that inherits from the built-in list type. The new type will be completely compatible with regular lists, but will have an additional increment() method that increases an internal counter. >>> >>> >>> >>> 6 >>> 1 >>> 2

import shoddy s = shoddy.Shoddy(range(3)) s.extend(s) print(len(s)) print(s.increment()) print(s.increment())

#include <Python.h> typedef struct { PyListObject list; int state; } Shoddy;

static PyObject * Shoddy_increment(Shoddy *self, PyObject *unused) { self->state++; return PyLong_FromLong(self->state); }

static PyMethodDef Shoddy_methods[] = { {"increment", (PyCFunction)Shoddy_increment, METH_NOARGS, PyDoc_STR("increment state counter")}, {NULL, NULL}, }; static int Shoddy_init(Shoddy *self, PyObject *args, PyObject *kwds) { if (PyList_Type.tp_init((PyObject *)self, args, kwds) < 0) return -1; self->state = 0; return 0; }

static PyTypeObject ShoddyType = { PyObject_HEAD_INIT(NULL) "shoddy.Shoddy", /* tp_name */ sizeof(Shoddy), /* tp_basicsize */ 0, /* tp_itemsize */ 0, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 48

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0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, 0, 0, 0, 0, 0, 0, 0, Shoddy_methods, 0, 0, 0, 0, 0, 0, 0, (initproc)Shoddy_init, 0, 0,

/* /* /* /* /* /* /* /* /* /* /*

tp_reserved */ tp_repr */ tp_as_number */ tp_as_sequence */ tp_as_mapping */ tp_hash */ tp_call */ tp_str */ tp_getattro */ tp_setattro */ tp_as_buffer */

/* /* /* /* /* /* /* /* /* /* /* /* /* /* /* /* /* /* /*

tp_flags */ tp_doc */ tp_traverse */ tp_clear */ tp_richcompare */ tp_weaklistoffset */ tp_iter */ tp_iternext */ tp_methods */ tp_members */ tp_getset */ tp_base */ tp_dict */ tp_descr_get */ tp_descr_set */ tp_dictoffset */ tp_init */ tp_alloc */ tp_new */

}; static PyModuleDef shoddymodule = { PyModuleDef_HEAD_INIT, "shoddy", "Shoddy module", -1, NULL, NULL, NULL, NULL, NULL }; PyMODINIT_FUNC PyInit_shoddy(void) { PyObject *m; ShoddyType.tp_base = &PyList_Type; if (PyType_Ready(&ShoddyType) < 0) return NULL; m = PyModule_Create(&shoddymodule); if (m == NULL) return NULL;

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Py_INCREF(&ShoddyType); PyModule_AddObject(m, "Shoddy", (PyObject *) &ShoddyType); return m; } As you can see, the source code closely resembles the Noddy examples in previous sections. We will break down the main differences between them. typedef struct { PyListObject list; int state; } Shoddy; The primary difference for derived type objects is that the base type’s object structure must be the first value. The base type will already include the PyObject_HEAD() at the beginning of its structure. When a Python object is a Shoddy instance, its PyObject* pointer can be safely cast to both PyListObject* and Shoddy*. static int Shoddy_init(Shoddy *self, PyObject *args, PyObject *kwds) { if (PyList_Type.tp_init((PyObject *)self, args, kwds) < 0) return -1; self->state = 0; return 0; } In the __init__ method for our type, we can see how to call through to the __init__ method of the base type. This pattern is important when writing a type with custom new and dealloc methods. The new method should not actually create the memory for the object with tp_alloc, that will be handled by the base class when calling its tp_new. When filling out the PyTypeObject() for the Shoddy type, you see a slot for tp_base(). Due to cross platform compiler issues, you can’t fill that field directly with the PyList_Type(); it can be done later in the module’s init() function. PyMODINIT_FUNC PyInit_shoddy(void) { PyObject *m; ShoddyType.tp_base = &PyList_Type; if (PyType_Ready(&ShoddyType) < 0) return NULL; m = PyModule_Create(&shoddymodule); if (m == NULL) return NULL; Py_INCREF(&ShoddyType); PyModule_AddObject(m, "Shoddy", (PyObject *) &ShoddyType); return m; } Before calling PyType_Ready(), the type structure must have the tp_base slot filled in. When we are deriving a new type, it is not necessary to fill out the tp_alloc slot with PyType_GenericNew() – the allocate function from the base type will be inherited.

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After that, calling PyType_Ready() and adding the type object to the module is the same as with the basic Noddy examples.

2.2 Type Methods This section aims to give a quick fly-by on the various type methods you can implement and what they do. Here is the definition of PyTypeObject, with some fields only used in debug builds omitted: typedef struct _typeobject { PyObject_VAR_HEAD char *tp_name; /* For printing, in format "<module>.<name>" */ int tp_basicsize, tp_itemsize; /* For allocation */ /* Methods to implement standard operations */ destructor tp_dealloc; printfunc tp_print; getattrfunc tp_getattr; setattrfunc tp_setattr; void *tp_reserved; reprfunc tp_repr; /* Method suites for standard classes */ PyNumberMethods *tp_as_number; PySequenceMethods *tp_as_sequence; PyMappingMethods *tp_as_mapping; /* More standard operations (here for binary compatibility) */ hashfunc tp_hash; ternaryfunc tp_call; reprfunc tp_str; getattrofunc tp_getattro; setattrofunc tp_setattro; /* Functions to access object as input/output buffer */ PyBufferProcs *tp_as_buffer; /* Flags to define presence of optional/expanded features */ long tp_flags; char *tp_doc; /* Documentation string */ /* call function for all accessible objects */ traverseproc tp_traverse; /* delete references to contained objects */ inquiry tp_clear; /* rich comparisons */ richcmpfunc tp_richcompare;

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/* weak reference enabler */ long tp_weaklistoffset; /* Iterators */ getiterfunc tp_iter; iternextfunc tp_iternext; /* Attribute descriptor and subclassing stuff */ struct PyMethodDef *tp_methods; struct PyMemberDef *tp_members; struct PyGetSetDef *tp_getset; struct _typeobject *tp_base; PyObject *tp_dict; descrgetfunc tp_descr_get; descrsetfunc tp_descr_set; long tp_dictoffset; initproc tp_init; allocfunc tp_alloc; newfunc tp_new; freefunc tp_free; /* Low-level free-memory routine */ inquiry tp_is_gc; /* For PyObject_IS_GC */ PyObject *tp_bases; PyObject *tp_mro; /* method resolution order */ PyObject *tp_cache; PyObject *tp_subclasses; PyObject *tp_weaklist; } PyTypeObject; Now that’s a lot of methods. Don’t worry too much though - if you have a type you want to define, the chances are very good that you will only implement a handful of these. As you probably expect by now, we’re going to go over this and give more information about the various handlers. We won’t go in the order they are defined in the structure, because there is a lot of historical baggage that impacts the ordering of the fields; be sure your type initialization keeps the fields in the right order! It’s often easiest to find an example that includes all the fields you need (even if they’re initialized to 0) and then change the values to suit your new type. char *tp_name; /* For printing */ The name of the type - as mentioned in the last section, this will appear in various places, almost entirely for diagnostic purposes. Try to choose something that will be helpful in such a situation! int tp_basicsize, tp_itemsize; /* For allocation */ These fields tell the runtime how much memory to allocate when new objects of this type are created. Python has some built-in support for variable length structures (think: strings, lists) which is where the tp_itemsize field comes in. This will be dealt with later. char *tp_doc; Here you can put a string (or its address) that you want returned when the Python script references obj.__doc__ to retrieve the doc string. Now we come to the basic type methods—the ones most extension types will implement.

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2.2.1 Finalization and De-allocation destructor tp_dealloc; This function is called when the reference count of the instance of your type is reduced to zero and the Python interpreter wants to reclaim it. If your type has memory to free or other clean-up to perform, put it here. The object itself needs to be freed here as well. Here is an example of this function: static void newdatatype_dealloc(newdatatypeobject * obj) { free(obj->obj_UnderlyingDatatypePtr); Py_TYPE(obj)->tp_free(obj); } One important requirement of the deallocator function is that it leaves any pending exceptions alone. This is important since deallocators are frequently called as the interpreter unwinds the Python stack; when the stack is unwound due to an exception (rather than normal returns), nothing is done to protect the deallocators from seeing that an exception has already been set. Any actions which a deallocator performs which may cause additional Python code to be executed may detect that an exception has been set. This can lead to misleading errors from the interpreter. The proper way to protect against this is to save a pending exception before performing the unsafe action, and restoring it when done. This can be done using the PyErr_Fetch() and PyErr_Restore() functions: static void my_dealloc(PyObject *obj) { MyObject *self = (MyObject *) obj; PyObject *cbresult; if (self->my_callback != NULL) { PyObject *err_type, *err_value, *err_traceback; int have_error = PyErr_Occurred() ? 1 : 0; if (have_error) PyErr_Fetch(&err_type, &err_value, &err_traceback); cbresult = PyObject_CallObject(self->my_callback, NULL); if (cbresult == NULL) PyErr_WriteUnraisable(self->my_callback); else Py_DECREF(cbresult); if (have_error) PyErr_Restore(err_type, err_value, err_traceback); Py_DECREF(self->my_callback); } Py_TYPE(obj)->tp_free((PyObject*)self); }

2.2.2 Object Presentation In Python, there are two ways to generate a textual representation of an object: the repr() function, and the str() function. (The print() function just calls str().) These handlers are both optional.

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reprfunc tp_repr; reprfunc tp_str; The tp_repr handler should return a string object containing a representation of the instance for which it is called. Here is a simple example: static PyObject * newdatatype_repr(newdatatypeobject * obj) { return PyString_FromFormat("Repr-ified_newdatatype{{size:\%d}}", obj->obj_UnderlyingDatatypePtr->size); } If no tp_repr handler is specified, the interpreter will supply a representation that uses the type’s tp_name and a uniquely-identifying value for the object. The tp_str handler is to str() what the tp_repr handler described above is to repr(); that is, it is called when Python code calls str() on an instance of your object. Its implementation is very similar to the tp_repr function, but the resulting string is intended for human consumption. If tp_str is not specified, the tp_repr handler is used instead. Here is a simple example: static PyObject * newdatatype_str(newdatatypeobject * obj) { return PyString_FromFormat("Stringified_newdatatype{{size:\%d}}", obj->obj_UnderlyingDatatypePtr->size); }

2.2.3 Attribute Management For every object which can support attributes, the corresponding type must provide the functions that control how the attributes are resolved. There needs to be a function which can retrieve attributes (if any are defined), and another to set attributes (if setting attributes is allowed). Removing an attribute is a special case, for which the new value passed to the handler is NULL. Python supports two pairs of attribute handlers; a type that supports attributes only needs to implement the functions for one pair. The difference is that one pair takes the name of the attribute as a char*, while the other accepts a PyObject*. Each type can use whichever pair makes more sense for the implementation’s convenience. getattrfunc setattrfunc /* ... */ getattrofunc setattrofunc

tp_getattr; tp_setattr;

/* char * version */

tp_getattro; tp_setattro;

/* PyObject * version */

If accessing attributes of an object is always a simple operation (this will be explained shortly), there are generic implementations which can be used to provide the PyObject* version of the attribute management functions. The actual need for type-specific attribute handlers almost completely disappeared starting with Python 2.2, though there are many examples which have not been updated to use some of the new generic mechanism that is available. Generic Attribute Management Most extension types only use simple attributes. So, what makes the attributes simple? There are only a couple of conditions that must be met:

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1. The name of the attributes must be known when PyType_Ready() is called. 2. No special processing is needed to record that an attribute was looked up or set, nor do actions need to be taken based on the value. Note that this list does not place any restrictions on the values of the attributes, when the values are computed, or how relevant data is stored. When PyType_Ready() is called, it uses three tables referenced by the type object to create descriptors which are placed in the dictionary of the type object. Each descriptor controls access to one attribute of the instance object. Each of the tables is optional; if all three are NULL, instances of the type will only have attributes that are inherited from their base type, and should leave the tp_getattro and tp_setattro fields NULL as well, allowing the base type to handle attributes. The tables are declared as three fields of the type object: struct PyMethodDef *tp_methods; struct PyMemberDef *tp_members; struct PyGetSetDef *tp_getset; If tp_methods is not NULL, it must refer to an array of PyMethodDef structures. Each entry in the table is an instance of this structure: typedef struct PyMethodDef { char *ml_name; PyCFunction ml_meth; int ml_flags; char ml_doc; * } PyMethodDef;

/* /* /* /*

method name */ implementation function */ flags */ docstring */

One entry should be defined for each method provided by the type; no entries are needed for methods inherited from a base type. One additional entry is needed at the end; it is a sentinel that marks the end of the array. The ml_name field of the sentinel must be NULL. XXX Need to refer to some unified discussion of the structure fields, shared with the next section. The second table is used to define attributes which map directly to data stored in the instance. A variety of primitive C types are supported, and access may be read-only or read-write. The structures in the table are defined as: typedef struct PyMemberDef { char *name; int type; int offset; int flags; char *doc; } PyMemberDef; For each entry in the table, a descriptor will be constructed and added to the type which will be able to extract a value from the instance structure. The type field should contain one of the type codes defined in the structmember.h header; the value will be used to determine how to convert Python values to and from C values. The flags field is used to store flags which control how the attribute can be accessed. XXX Need to move some of this to a shared section! The following flag constants are defined in structmember.h; they may be combined using bitwise-OR. Constant READONLY READ_RESTRICTED WRITE_RESTRICTED RESTRICTED

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Meaning Never writable. Not readable in restricted mode. Not writable in restricted mode. Not readable or writable in restricted mode.

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An interesting advantage of using the tp_members table to build descriptors that are used at runtime is that any attribute defined this way can have an associated doc string simply by providing the text in the table. An application can use the introspection API to retrieve the descriptor from the class object, and get the doc string using its __doc__ attribute. As with the tp_methods table, a sentinel entry with a name value of NULL is required. Type-specific Attribute Management For simplicity, only the char* version will be demonstrated here; the type of the name parameter is the only difference between the char* and PyObject* flavors of the interface. This example effectively does the same thing as the generic example above, but does not use the generic support added in Python 2.2. It explains how the handler functions are called, so that if you do need to extend their functionality, you’ll understand what needs to be done. The tp_getattr handler is called when the object requires an attribute look-up. It is called in the same situations where the __getattr__() method of a class would be called. Here is an example: static PyObject * newdatatype_getattr(newdatatypeobject *obj, char *name) { if (strcmp(name, "data") == 0) { return PyInt_FromLong(obj->data); } PyErr_Format(PyExc_AttributeError, "’%.50s’ object has no attribute ’%.400s’", tp->tp_name, name); return NULL; } The tp_setattr handler is called when the __setattr__() or __delattr__() method of a class instance would be called. When an attribute should be deleted, the third parameter will be NULL. Here is an example that simply raises an exception; if this were really all you wanted, the tp_setattr handler should be set to NULL. static int newdatatype_setattr(newdatatypeobject *obj, char *name, PyObject *v) { (void)PyErr_Format(PyExc_RuntimeError, "Read-only attribute: \%s", name); return -1; }

2.2.4 Object Comparison richcmpfunc tp_richcompare; The tp_richcompare handler is called when comparisons are needed. It is analogous to the rich comparison methods (in The Python Language Reference), like __lt__(), and also called by PyObject_RichCompare() and PyObject_RichCompareBool(). This function is called with two Python objects and the operator as arguments, where the operator is one of Py_EQ, Py_NE, Py_LE, Py_GT, Py_LT or Py_GT. It should compare the two objects with respect to the specified operator

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and return Py_True or Py_False if the comparison is successful, Py_NotImplemented to indicate that comparison is not implemented and the other object’s comparison method should be tried, or NULL if an exception was set. Here is a sample implementation, for a datatype that is considered equal if the size of an internal pointer is equal: static int newdatatype_richcmp(PyObject *obj1, PyObject *obj2, int op) { PyObject *result; int c, size1, size2; /* code to make sure that both arguments are of type newdatatype omitted */ size1 = obj1->obj_UnderlyingDatatypePtr->size; size2 = obj2->obj_UnderlyingDatatypePtr->size; switch (op) { case Py_LT: c = size1 < size2; break; case Py_LE: c = size1 <= size2; break; case Py_EQ: c = size1 == size2; break; case Py_NE: c = size1 != size2; break; case Py_GT: c = size1 > size2; break; case Py_GE: c = size1 >= size2; break; } result = c ? Py_True : Py_False; Py_INCREF(result); return result; }

2.2.5 Abstract Protocol Support Python supports a variety of abstract ‘protocols;’ the specific interfaces provided to use these interfaces are documented in Abstract Objects Layer (in The Python/C API). A number of these abstract interfaces were defined early in the development of the Python implementation. In particular, the number, mapping, and sequence protocols have been part of Python since the beginning. Other protocols have been added over time. For protocols which depend on several handler routines from the type implementation, the older protocols have been defined as optional blocks of handlers referenced by the type object. For newer protocols there are additional slots in the main type object, with a flag bit being set to indicate that the slots are present and should be checked by the interpreter. (The flag bit does not indicate that the slot values are non-NULL. The flag may be set to indicate the presence of a slot, but a slot may still be unfilled.) PyNumberMethods tp_as_number; PySequenceMethods tp_as_sequence; PyMappingMethods tp_as_mapping; If you wish your object to be able to act like a number, a sequence, or a mapping object, then you place the address of a structure that implements the C type PyNumberMethods, PySequenceMethods, or PyMappingMethods, respectively. It is up to you to fill in this structure with appropriate values. You can find examples of the use of each of these in the Objects directory of the Python source distribution. hashfunc tp_hash; This function, if you choose to provide it, should return a hash number for an instance of your data type. Here is a moderately pointless example: 2.2. Type Methods

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static long newdatatype_hash(newdatatypeobject *obj) { long result; result = obj->obj_UnderlyingDatatypePtr->size; result = result * 3; return result; } ternaryfunc tp_call; This function is called when an instance of your data type is “called”, for example, if obj1 is an instance of your data type and the Python script contains obj1(’hello’), the tp_call handler is invoked. This function takes three arguments: 1. arg1 is the instance of the data type which is the subject of the call. If the call is obj1(’hello’), then arg1 is obj1. 2. arg2 is a tuple containing the arguments to the call. You can use PyArg_ParseTuple() to extract the arguments. 3. arg3 is a dictionary of keyword arguments that were passed. If this is non-NULL and you support keyword arguments, use PyArg_ParseTupleAndKeywords() to extract the arguments. If you do not want to support keyword arguments and this is non-NULL, raise a TypeError with a message saying that keyword arguments are not supported. Here is a desultory example of the implementation of the call function. /* Implement the call function. obj1 is the instance receiving the call. * obj2 is a tuple containing the arguments to the call, in this * case 3 strings. * */ static PyObject * newdatatype_call(newdatatypeobject *obj, PyObject *args, PyObject *other) { PyObject *result; char *arg1; char *arg2; char *arg3; if (!PyArg_ParseTuple(args, "sss:call", &arg1, &arg2, &arg3)) { return NULL; } result = PyString_FromFormat( "Returning -- value: [\%d] arg1: [\%s] arg2: [\%s] arg3: [\%s]\n", obj->obj_UnderlyingDatatypePtr->size, arg1, arg2, arg3); printf("\%s", PyString_AS_STRING(result)); return result; } XXX some fields need to be added here... /* Iterators */ getiterfunc tp_iter; iternextfunc tp_iternext;

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These functions provide support for the iterator protocol. Any object which wishes to support iteration over its contents (which may be generated during iteration) must implement the tp_iter handler. Objects which are returned by a tp_iter handler must implement both the tp_iter and tp_iternext handlers. Both handlers take exactly one parameter, the instance for which they are being called, and return a new reference. In the case of an error, they should set an exception and return NULL. For an object which represents an iterable collection, the tp_iter handler must return an iterator object. The iterator object is responsible for maintaining the state of the iteration. For collections which can support multiple iterators which do not interfere with each other (as lists and tuples do), a new iterator should be created and returned. Objects which can only be iterated over once (usually due to side effects of iteration) should implement this handler by returning a new reference to themselves, and should also implement the tp_iternext handler. File objects are an example of such an iterator. Iterator objects should implement both handlers. The tp_iter handler should return a new reference to the iterator (this is the same as the tp_iter handler for objects which can only be iterated over destructively). The tp_iternext handler should return a new reference to the next object in the iteration if there is one. If the iteration has reached the end, it may return NULL without setting an exception or it may set StopIteration; avoiding the exception can yield slightly better performance. If an actual error occurs, it should set an exception and return NULL.

2.2.6 Weak Reference Support One of the goals of Python’s weak-reference implementation is to allow any type to participate in the weak reference mechanism without incurring the overhead on those objects which do not benefit by weak referencing (such as numbers). For an object to be weakly referencable, the extension must include a PyObject* field in the instance structure for the use of the weak reference mechanism; it must be initialized to NULL by the object’s constructor. It must also set the tp_weaklistoffset field of the corresponding type object to the offset of the field. For example, the instance type is defined with the following structure: typedef struct { PyObject_HEAD PyClassObject *in_class; /* The class object */ PyObject in_dict; /* A dictionary */ * PyObject in_weakreflist; /* List of weak references */ * } PyInstanceObject; The statically-declared type object for instances is defined this way: PyTypeObject PyInstance_Type = { PyVarObject_HEAD_INIT(&PyType_Type, 0) 0, "module.instance", /* Lots of stuff omitted for brevity... */ Py_TPFLAGS_DEFAULT, 0, 0, 0, 0, offsetof(PyInstanceObject, in_weakreflist),

/* /* /* /* /* /*

tp_flags */ tp_doc */ tp_traverse */ tp_clear */ tp_richcompare */ tp_weaklistoffset */

}; The type constructor is responsible for initializing the weak reference list to NULL:

2.2. Type Methods

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static PyObject * instance_new() { /* Other initialization stuff omitted for brevity */ self->in_weakreflist = NULL; return (PyObject *) self; } The only further addition is that the destructor needs to call the weak reference manager to clear any weak references. This should be done before any other parts of the destruction have occurred, but is only required if the weak reference list is non-NULL: static void instance_dealloc(PyInstanceObject *inst) { /* Allocate temporaries if needed, but do not begin destruction just yet. */ if (inst->in_weakreflist != NULL) PyObject_ClearWeakRefs((PyObject *) inst); /* Proceed with object destruction normally. */ }

2.2.7 More Suggestions Remember that you can omit most of these functions, in which case you provide 0 as a value. There are type definitions for each of the functions you must provide. They are in object.h in the Python include directory that comes with the source distribution of Python. In order to learn how to implement any specific method for your new data type, do the following: Download and unpack the Python source distribution. Go to the Objects directory, then search the C source files for tp_ plus the function you want (for example, tp_richcompare). You will find examples of the function you want to implement. When you need to verify that an object is an instance of the type you are implementing, use the PyObject_TypeCheck() function. A sample of its use might be something like the following: if (! PyObject_TypeCheck(some_object, &MyType)) { PyErr_SetString(PyExc_TypeError, "arg #1 not a mything"); return NULL; }

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BUILDING C AND C++ EXTENSIONS WITH DISTUTILS Starting in Python 1.4, Python provides, on Unix, a special make file for building make files for building dynamicallylinked extensions and custom interpreters. Starting with Python 2.0, this mechanism (known as related to Makefile.pre.in, and Setup files) is no longer supported. Building custom interpreters was rarely used, and extension modules can be built using distutils. Building an extension module using distutils requires that distutils is installed on the build machine, which is included in Python 2.x and available separately for Python 1.5. Since distutils also supports creation of binary packages, users don’t necessarily need a compiler and distutils to install the extension. A distutils package contains a driver script, setup.py. This is a plain Python file, which, in the most simple case, could look like this: from distutils.core import setup, Extension module1 = Extension(’demo’, sources = [’demo.c’]) setup (name = ’PackageName’, version = ’1.0’, description = ’This is a demo package’, ext_modules = [module1]) With this setup.py, and a file demo.c, running python setup.py build will compile demo.c, and produce an extension module named demo in the build directory. Depending on the system, the module file will end up in a subdirectory build/lib.system, and may have a name like demo.so or demo.pyd. In the setup.py, all execution is performed by calling the setup function. This takes a variable number of keyword arguments, of which the example above uses only a subset. Specifically, the example specifies meta-information to build packages, and it specifies the contents of the package. Normally, a package will contain of addition modules, like Python source modules, documentation, subpackages, etc. Please refer to the distutils documentation in Distributing Python Modules (in Distributing Python Modules) to learn more about the features of distutils; this section explains building extension modules only. It is common to pre-compute arguments to setup(), to better structure the driver script. In the example above, theext_modules argument to setup() is a list of extension modules, each of which is an instance of the Extension. In the example, the instance defines an extension named demo which is build by compiling a single source file, demo.c.

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In many cases, building an extension is more complex, since additional preprocessor defines and libraries may be needed. This is demonstrated in the example below. from distutils.core import setup, Extension module1 = Extension(’demo’, define_macros = [(’MAJOR_VERSION’, ’1’), (’MINOR_VERSION’, ’0’)], include_dirs = [’/usr/local/include’], libraries = [’tcl83’], library_dirs = [’/usr/local/lib’], sources = [’demo.c’]) setup (name = ’PackageName’, version = ’1.0’, description = ’This is a demo package’, author = ’Martin v. Loewis’, author_email = ’martin@v.loewis.de’, url = ’http://docs.python.org/extending/building’, long_description = ’’’ This is really just a demo package. ’’’, ext_modules = [module1]) In this example, setup() is called with additional meta-information, which is recommended when distribution packages have to be built. For the extension itself, it specifies preprocessor defines, include directories, library directories, and libraries. Depending on the compiler, distutils passes this information in different ways to the compiler. For example, on Unix, this may result in the compilation commands

gcc -DNDEBUG -g -O3 -Wall -Wstrict-prototypes -fPIC -DMAJOR_VERSION=1 -DMINOR_VERSION=0 -I/

gcc -shared build/temp.linux-i686-2.2/demo.o -L/usr/local/lib -ltcl83 -o build/lib.linux-i6 These lines are for demonstration purposes only; distutils users should trust that distutils gets the invocations right.

3.1 Distributing your extension modules When an extension has been successfully build, there are three ways to use it. End-users will typically want to install the module, they do so by running python setup.py install Module maintainers should produce source packages; to do so, they run python setup.py sdist In some cases, additional files need to be included in a source distribution; this is done through a MANIFEST.in file; see the distutils documentation for details. If the source distribution has been build successfully, maintainers can also create binary distributions. Depending on the platform, one of the following commands can be used to do so. python setup.py bdist_wininst python setup.py bdist_rpm python setup.py bdist_dumb

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BUILDING C AND C++ EXTENSIONS ON WINDOWS This chapter briefly explains how to create a Windows extension module for Python using Microsoft Visual C++, and follows with more detailed background information on how it works. The explanatory material is useful for both the Windows programmer learning to build Python extensions and the Unix programmer interested in producing software which can be successfully built on both Unix and Windows. Module authors are encouraged to use the distutils approach for building extension modules, instead of the one described in this section. You will still need the C compiler that was used to build Python; typically Microsoft Visual C++. Note: This chapter mentions a number of filenames that include an encoded Python version number. These filenames are represented with the version number shown as XY; in practice, ’X’ will be the major version number and ’Y’ will be the minor version number of the Python release you’re working with. For example, if you are using Python 2.2.1, XY will actually be 22.

4.1 A Cookbook Approach There are two approaches to building extension modules on Windows, just as there are on Unix: use the distutils package to control the build process, or do things manually. The distutils approach works well for most extensions; documentation on using distutils to build and package extension modules is available in Distributing Python Modules (in Distributing Python Modules). This section describes the manual approach to building Python extensions written in C or C++. To build extensions using these instructions, you need to have a copy of the Python sources of the same version as your installed Python. You will need Microsoft Visual C++ “Developer Studio”; project files are supplied for VC++ version 7.1, but you can use older versions of VC++. Notice that you should use the same version of VC++that was used to build Python itself. The example files described here are distributed with the Python sources in the PC\example_nt\ directory. 1. Copy the example files — The example_nt directory is a subdirectory of the PC directory, in order to keep all the PC-specific files under the same directory in the source distribution. However, the example_nt directory can’t actually be used from this location. You first need to copy or move it up one level, so that example_nt is a sibling of the PC and Include directories. Do all your work from within this new location. 2. Open the project — From VC++, use the File → Open Solution dialog (not File → Open!). Navigate to and select the file example.sln, in the copy of the example_nt directory you made above. Click Open. 3. Build the example DLL — In order to check that everything is set up right, try building:

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4. Select a configuration. This step is optional. Choose Build → Configuration Manager → Active Solution Configuration and select either Release or Debug. If you skip this step, VC++ will use the Debug configuration by default. 5. Build the DLL. Choose Build → Build Solution. This creates all intermediate and result files in a subdirectory called either Debug or Release, depending on which configuration you selected in the preceding step. 6. Testing the debug-mode DLL — Once the Debug build has succeeded, bring up a DOS box, and change to the example_nt\Debug directory. You should now be able to repeat the following session (C> is the DOS prompt, >>> is the Python prompt; note that build information and various debug output from Python may not match this screen dump exactly): C>..\..\PCbuild\python_d Adding parser accelerators ... Done. Python 2.2 (#28, Dec 19 2001, 23:26:37) [MSC 32 bit (Intel)] on win32 Type "copyright", "credits" or "license" for more information. >>> import example [4897 refs] >>> example.foo() Hello, world [4903 refs] >>> Congratulations! You’ve successfully built your first Python extension module. 7. Creating your own project — Choose a name and create a directory for it. Copy your C sources into it. Note that the module source file name does not necessarily have to match the module name, but the name of the initialization function should match the module name — you can only import a module spam if its initialization function is called initspam(), and it should call Py_InitModule() with the string "spam" as its first argument (use the minimal example.c in this directory as a guide). By convention, it lives in a file called spam.c or spammodule.c. The output file should be called spam.pyd (in Release mode) or spam_d.pyd (in Debug mode). The extension .pyd was chosen to avoid confusion with a system library spam.dll to which your module could be a Python interface. Now your options are: 8. Copy example.sln and example.vcproj, rename them to spam.*, and edit them by hand, or 9. Create a brand new project; instructions are below. In either case, copy example_nt\example.def to spam\spam.def, and edit the new spam.def so its second line contains the string ‘initspam‘. If you created a new project yourself, add the file spam.def to the project now. (This is an annoying little file with only two lines. An alternative approach is to forget about the .def file, and add the option /export:initspam somewhere to the Link settings, by manually editing the setting in Project Properties dialog). 10. Creating a brand new project — Use the File → New → Project dialog to create a new Project Workspace. Select Visual C++ Projects/Win32/ Win32 Project, enter the name (spam), and make sure the Location is set to parent of the spam directory you have created (which should be a direct subdirectory of the Python build tree, a sibling of Include and PC). Select Win32 as the platform (in my version, this is the only choice). Make sure the Create new workspace radio button is selected. Click OK. You should now create the file spam.def as instructed in the previous section. Add the source files to the project, using Project → Add Existing Item. Set the pattern to *.* and select both spam.c and spam.def and click OK. (Inserting them one by one is fine too.) Now open the Project → spam properties dialog. You only need to change a few settings. Make sure All Configurations is selected from the Settings for: dropdown list. Select the C/C++ tab. Choose the General

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category in the popup menu at the top. Type the following text in the entry box labeled Additional Include Directories: ..\Include,..\PC Then, choose the General category in the Linker tab, and enter ..\PCbuild in the text box labelled Additional library Directories. Now you need to add some mode-specific settings: Select Release in the Configuration dropdown list. Choose the Link tab, choose the Input category, and append pythonXY.lib to the list in the Additional Dependencies box. Select Debug in the Configuration dropdown list, and append pythonXY_d.lib to the list in the Additional Dependencies box. Then click the C/C++ tab, select Code Generation, and select Multi-threaded Debug DLL from the Runtime library dropdown list. Select Release again from the Configuration dropdown list. Select Multi-threaded DLL from the Runtime library dropdown list. If your module creates a new type, you may have trouble with this line: PyVarObject_HEAD_INIT(&PyType_Type, 0) Static type object initializers in extension modules may cause compiles to fail with an error message like “initializer not a constant”. This shows up when building DLL under MSVC. Change it to: PyVarObject_HEAD_INIT(NULL, 0) and add the following to the module initialization function: MyObject_Type.ob_type = &PyType_Type;

4.2 Differences Between Unix and Windows Unix and Windows use completely different paradigms for run-time loading of code. Before you try to build a module that can be dynamically loaded, be aware of how your system works. In Unix, a shared object (.so) file contains code to be used by the program, and also the names of functions and data that it expects to find in the program. When the file is joined to the program, all references to those functions and data in the file’s code are changed to point to the actual locations in the program where the functions and data are placed in memory. This is basically a link operation. In Windows, a dynamic-link library (.dll) file has no dangling references. Instead, an access to functions or data goes through a lookup table. So the DLL code does not have to be fixed up at runtime to refer to the program’s memory; instead, the code already uses the DLL’s lookup table, and the lookup table is modified at runtime to point to the functions and data. In Unix, there is only one type of library file (.a) which contains code from several object files (.o). During the link step to create a shared object file (.so), the linker may find that it doesn’t know where an identifier is defined. The linker will look for it in the object files in the libraries; if it finds it, it will include all the code from that object file. In Windows, there are two types of library, a static library and an import library (both called .lib). A static library is like a Unix .a file; it contains code to be included as necessary. An import library is basically used only to reassure the linker that a certain identifier is legal, and will be present in the program when the DLL is loaded. So the linker uses the information from the import library to build the lookup table for using identifiers that are not included in the DLL. When an application or a DLL is linked, an import library may be generated, which will need to be used for all future DLLs that depend on the symbols in the application or DLL.

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Suppose you are building two dynamic-load modules, B and C, which should share another block of code A. On Unix, you would not pass A.a to the linker for B.so and C.so; that would cause it to be included twice, so that B and C would each have their own copy. In Windows, building A.dll will also build A.lib. You do pass A.lib to the linker for B and C. A.lib does not contain code; it just contains information which will be used at runtime to access A’s code. In Windows, using an import library is sort of like using import spam; it gives you access to spam’s names, but does not create a separate copy. On Unix, linking with a library is more like from spam import *; it does create a separate copy.

4.3 Using DLLs in Practice Windows Python is built in Microsoft Visual C++; using other compilers may or may not work (though Borland seems to). The rest of this section is MSVC++ specific. When creating DLLs in Windows, you must pass pythonXY.lib to the linker. To build two DLLs, spam and ni (which uses C functions found in spam), you could use these commands: cl /LD /I/python/include spam.c ../libs/pythonXY.lib cl /LD /I/python/include ni.c spam.lib ../libs/pythonXY.lib The first command created three files: spam.obj, spam.dll and spam.lib. Spam.dll does not contain any Python functions (such as PyArg_ParseTuple()), but it does know how to find the Python code thanks to pythonXY.lib. The second command created ni.dll (and .obj and .lib), which knows how to find the necessary functions from spam, and also from the Python executable. Not every identifier is exported to the lookup table. If you want any other modules (including Python) to be able to see your identifiers, you have to say _declspec(dllexport), as in void _declspec(dllexport) initspam(void) or PyObject _declspec(dllexport) *NiGetSpamData(void). Developer Studio will throw in a lot of import libraries that you do not really need, adding about 100K to your executable. To get rid of them, use the Project Settings dialog, Link tab, to specify ignore default libraries. Add the correct msvcrtxx.lib to the list of libraries.

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EMBEDDING PYTHON IN ANOTHER APPLICATION The previous chapters discussed how to extend Python, that is, how to extend the functionality of Python by attaching a library of C functions to it. It is also possible to do it the other way around: enrich your C/C++ application by embedding Python in it. Embedding provides your application with the ability to implement some of the functionality of your application in Python rather than C or C++. This can be used for many purposes; one example would be to allow users to tailor the application to their needs by writing some scripts in Python. You can also use it yourself if some of the functionality can be written in Python more easily. Embedding Python is similar to extending it, but not quite. The difference is that when you extend Python, the main program of the application is still the Python interpreter, while if you embed Python, the main program may have nothing to do with Python — instead, some parts of the application occasionally call the Python interpreter to run some Python code. So if you are embedding Python, you are providing your own main program. One of the things this main program has to do is initialize the Python interpreter. At the very least, you have to call the function Py_Initialize(). There are optional calls to pass command line arguments to Python. Then later you can call the interpreter from any part of the application. There are several different ways to call the interpreter: you can pass a string containing Python statements to PyRun_SimpleString(), or you can pass a stdio file pointer and a file name (for identification in error messages only) to PyRun_SimpleFile(). You can also call the lower-level operations described in the previous chapters to construct and use Python objects. A simple demo of embedding Python can be found in the directory Demo/embed/ of the source distribution. See Also: Python/C API Reference Manual (in The Python/C API) The details of Python’s C interface are given in this manual. A great deal of necessary information can be found here.

5.1 Very High Level Embedding The simplest form of embedding Python is the use of the very high level interface. This interface is intended to execute a Python script without needing to interact with the application directly. This can for example be used to perform some operation on a file. #include <Python.h> int main(int argc, char *argv[])

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{ Py_Initialize(); PyRun_SimpleString("from time import time,ctime\n" "print(’Today is’, ctime(time()))\n"); Py_Finalize(); return 0; } The above code first initializes the Python interpreter with Py_Initialize(), followed by the execution of a hardcoded Python script that print the date and time. Afterwards, the Py_Finalize() call shuts the interpreter down, followed by the end of the program. In a real program, you may want to get the Python script from another source, perhaps a text-editor routine, a file, or a database. Getting the Python code from a file can better be done by using the PyRun_SimpleFile() function, which saves you the trouble of allocating memory space and loading the file contents.

5.2 Beyond Very High Level Embedding: An overview The high level interface gives you the ability to execute arbitrary pieces of Python code from your application, but exchanging data values is quite cumbersome to say the least. If you want that, you should use lower level calls. At the cost of having to write more C code, you can achieve almost anything. It should be noted that extending Python and embedding Python is quite the same activity, despite the different intent. Most topics discussed in the previous chapters are still valid. To show this, consider what the extension code from Python to C really does: 1. Convert data values from Python to C, 2. Perform a function call to a C routine using the converted values, and 3. Convert the data values from the call from C to Python. When embedding Python, the interface code does: 1. Convert data values from C to Python, 2. Perform a function call to a Python interface routine using the converted values, and 3. Convert the data values from the call from Python to C. As you can see, the data conversion steps are simply swapped to accommodate the different direction of the crosslanguage transfer. The only difference is the routine that you call between both data conversions. When extending, you call a C routine, when embedding, you call a Python routine. This chapter will not discuss how to convert data from Python to C and vice versa. Also, proper use of references and dealing with errors is assumed to be understood. Since these aspects do not differ from extending the interpreter, you can refer to earlier chapters for the required information.

5.3 Pure Embedding The first program aims to execute a function in a Python script. Like in the section about the very high level interface, the Python interpreter does not directly interact with the application (but that will change in the next section). The code to run a function defined in a Python script is: #include <Python.h> int

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main(int argc, char *argv[]) { PyObject *pName, *pModule, *pDict, *pFunc; PyObject *pArgs, *pValue; int i; if (argc < 3) { fprintf(stderr,"Usage: call pythonfile funcname [args]\n"); return 1; } Py_Initialize(); pName = PyUnicode_FromString(argv[1]); /* Error checking of pName left out */ pModule = PyImport_Import(pName); Py_DECREF(pName); if (pModule != NULL) { pFunc = PyObject_GetAttrString(pModule, argv[2]); /* pFunc is a new reference */ if (pFunc && PyCallable_Check(pFunc)) { pArgs = PyTuple_New(argc - 3); for (i = 0; i < argc - 3; ++i) { pValue = PyLong_FromLong(atoi(argv[i + 3])); if (!pValue) { Py_DECREF(pArgs); Py_DECREF(pModule); fprintf(stderr, "Cannot convert argument\n"); return 1; } /* pValue reference stolen here: */ PyTuple_SetItem(pArgs, i, pValue); } pValue = PyObject_CallObject(pFunc, pArgs); Py_DECREF(pArgs); if (pValue != NULL) { printf("Result of call: %ld\n", PyLong_AsLong(pValue)); Py_DECREF(pValue); } else { Py_DECREF(pFunc); Py_DECREF(pModule); PyErr_Print(); fprintf(stderr,"Call failed\n"); return 1; } } else { if (PyErr_Occurred()) PyErr_Print(); fprintf(stderr, "Cannot find function \"%s\"\n", argv[2]); }

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Py_XDECREF(pFunc); Py_DECREF(pModule); } else { PyErr_Print(); fprintf(stderr, "Failed to load \"%s\"\n", argv[1]); return 1; } Py_Finalize(); return 0; } This code loads a Python script using argv[1], and calls the function named in argv[2]. Its integer arguments are the other values of the argv array. If you compile and link this program (let’s call the finished executable call), and use it to execute a Python script, such as: def multiply(a,b): print("Will compute", a, "times", b) c = 0 for i in range(0, a): c = c + b return c then the result should be: $ call multiply multiply 3 2 Will compute 3 times 2 Result of call: 6 Although the program is quite large for its functionality, most of the code is for data conversion between Python and C, and for error reporting. The interesting part with respect to embedding Python starts with Py_Initialize(); pName = PyString_FromString(argv[1]); /* Error checking of pName left out */ pModule = PyImport_Import(pName); After initializing the interpreter, the script is loaded using PyImport_Import(). This routine needs a Python string as its argument, which is constructed using the PyString_FromString() data conversion routine. pFunc = PyObject_GetAttrString(pModule, argv[2]); /* pFunc is a new reference */ if (pFunc && PyCallable_Check(pFunc)) { ... } Py_XDECREF(pFunc); Once the script is loaded, the name we’re looking for is retrieved using PyObject_GetAttrString(). If the name exists, and the object returned is callable, you can safely assume that it is a function. The program then proceeds by constructing a tuple of arguments as normal. The call to the Python function is then made with: pValue = PyObject_CallObject(pFunc, pArgs); Upon return of the function, pValue is either NULL or it contains a reference to the return value of the function. Be sure to release the reference after examining the value.

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5.4 Extending Embedded Python Until now, the embedded Python interpreter had no access to functionality from the application itself. The Python API allows this by extending the embedded interpreter. That is, the embedded interpreter gets extended with routines provided by the application. While it sounds complex, it is not so bad. Simply forget for a while that the application starts the Python interpreter. Instead, consider the application to be a set of subroutines, and write some glue code that gives Python access to those routines, just like you would write a normal Python extension. For example: static int numargs=0; /* Return the number of arguments of the application command line */ static PyObject* emb_numargs(PyObject *self, PyObject *args) { if(!PyArg_ParseTuple(args, ":numargs")) return NULL; return PyLong_FromLong(numargs); } static PyMethodDef EmbMethods[] = { {"numargs", emb_numargs, METH_VARARGS, "Return the number of arguments received by the process."}, {NULL, NULL, 0, NULL} }; static PyModuleDef EmbModule = { PyModuleDef_HEAD_INIT, "emb", NULL, -1, EmbMethods, NULL, NULL, NULL, NULL }; static PyObject* PyInit_emb(void) { return PyModule_Create(&EmbModule); } Insert the above code just above the main() function. Also, insert the following two statements before the call to Py_Initialize(): numargs = argc; PyImport_AppendInittab("emb", &PyInit_emb); These two lines initialize the numargs variable, and make the emb.numargs() function accessible to the embedded Python interpreter. With these extensions, the Python script can do things like import emb print("Number of arguments", emb.numargs()) In a real application, the methods will expose an API of the application to Python.

5.5 Embedding Python in C++ It is also possible to embed Python in a C++ program; precisely how this is done will depend on the details of the C++ system used; in general you will need to write the main program in C++, and use the C++ compiler to compile and link your program. There is no need to recompile Python itself using C++. 5.4. Extending Embedded Python

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5.6 Linking Requirements While the configure script shipped with the Python sources will correctly build Python to export the symbols needed by dynamically linked extensions, this is not automatically inherited by applications which embed the Python library statically, at least on Unix. This is an issue when the application is linked to the static runtime library (libpython.a) and needs to load dynamic extensions (implemented as .so files). The problem is that some entry points are defined by the Python runtime solely for extension modules to use. If the embedding application does not use any of these entry points, some linkers will not include those entries in the symbol table of the finished executable. Some additional options are needed to inform the linker not to remove these symbols. Determining the right options to use for any given platform can be quite difficult, but fortunately the Python configuration already has those values. To retrieve them from an installed Python interpreter, start an interactive interpreter and have a short session like this: >>> import distutils.sysconfig >>> distutils.sysconfig.get_config_var(’LINKFORSHARED’) ’-Xlinker -export-dynamic’ The contents of the string presented will be the options that should be used. If the string is empty, there’s no need to add any additional options. The LINKFORSHARED definition corresponds to the variable of the same name in Python’s top-level Makefile.

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A

GLOSSARY >>> The default Python prompt of the interactive shell. Often seen for code examples which can be executed interactively in the interpreter. ... The default Python prompt of the interactive shell when entering code for an indented code block or within a pair of matching left and right delimiters (parentheses, square brackets or curly braces). 2to3 A tool that tries to convert Python 2.x code to Python 3.x code by handling most of the incompatibilities which can be detected by parsing the source and traversing the parse tree. 2to3 is available in the standard library as lib2to3; a standalone entry point is provided as Tools/scripts/2to3. See 2to3 - Automated Python 2 to 3 code translation (in The Python Library Reference). abstract base class Abstract Base Classes (abbreviated ABCs) complement duck-typing by providing a way to define interfaces when other techniques like hasattr() would be clumsy. Python comes with many built-in ABCs for data structures (in the collections module), numbers (in the numbers module), and streams (in the io module). You can create your own ABC with the abc module. argument A value passed to a function or method, assigned to a named local variable in the function body. A function or method may have both positional arguments and keyword arguments in its definition. Positional and keyword arguments may be variable-length: * accepts or passes (if in the function definition or call) several positional arguments in a list, while ** does the same for keyword arguments in a dictionary. Any expression may be used within the argument list, and the evaluated value is passed to the local variable. attribute A value associated with an object which is referenced by name using dotted expressions. For example, if an object o has an attribute a it would be referenced as o.a. BDFL Benevolent Dictator For Life, a.k.a. Guido van Rossum, Python’s creator. bytecode Python source code is compiled into bytecode, the internal representation of a Python program in the interpreter. The bytecode is also cached in .pyc and .pyo files so that executing the same file is faster the second time (recompilation from source to bytecode can be avoided). This “intermediate language� is said to run on a virtual machine that executes the machine code corresponding to each bytecode. A list of bytecode instructions can be found in the documentation for the dis module (in The Python Library Reference). class A template for creating user-defined objects. Class definitions normally contain method definitions which operate on instances of the class. coercion The implicit conversion of an instance of one type to another during an operation which involves two arguments of the same type. For example, int(3.15) converts the floating point number to the integer 3, but in 3+4.5, each argument is of a different type (one int, one float), and both must be converted to the same type before they can be added or it will raise a TypeError. Without coercion, all arguments of even compatible

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types would have to be normalized to the same value by the programmer, e.g., float(3)+4.5 rather than just 3+4.5. complex number An extension of the familiar real number system in which all numbers are expressed as a sum of a real part and an imaginary part. Imaginary numbers are real multiples of the imaginary unit (the square root of -1), often written i in mathematics or j in engineering. Python has built-in support for complex numbers, which are written with this latter notation; the imaginary part is written with a j suffix, e.g., 3+1j. To get access to complex equivalents of the math module, use cmath. Use of complex numbers is a fairly advanced mathematical feature. If you’re not aware of a need for them, it’s almost certain you can safely ignore them. context manager An object which controls the environment seen in a with statement by defining __enter__() and __exit__() methods. See PEP 343. CPython The canonical implementation of the Python programming language, as distributed on python.org. The term “CPython” is used when necessary to distinguish this implementation from others such as Jython or IronPython. decorator A function returning another function, usually applied as a function transformation using the @wrapper syntax. Common examples for decorators are classmethod() and staticmethod(). The decorator syntax is merely syntactic sugar, the following two function definitions are semantically equivalent: def f(...): ... f = staticmethod(f) @staticmethod def f(...): ... The same concept exists for classes, but is less commonly used there. See the documentation for function definitions (in The Python Language Reference) and class definitions (in The Python Language Reference) for more about decorators. descriptor Any object which defines the methods __get__(), __set__(), or __delete__(). When a class attribute is a descriptor, its special binding behavior is triggered upon attribute lookup. Normally, using a.b to get, set or delete an attribute looks up the object named b in the class dictionary for a, but if b is a descriptor, the respective descriptor method gets called. Understanding descriptors is a key to a deep understanding of Python because they are the basis for many features including functions, methods, properties, class methods, static methods, and reference to super classes. For more information about descriptors’ methods, see Implementing Descriptors (in The Python Language Reference). dictionary An associative array, where arbitrary keys are mapped to values. The keys can be any object with __hash__() function and __eq__() methods. Called a hash in Perl. docstring A string literal which appears as the first expression in a class, function or module. While ignored when the suite is executed, it is recognized by the compiler and put into the __doc__ attribute of the enclosing class, function or module. Since it is available via introspection, it is the canonical place for documentation of the object. duck-typing A programming style which does not look at an object’s type to determine if it has the right interface; instead, the method or attribute is simply called or used (“If it looks like a duck and quacks like a duck, it must be a duck.”) By emphasizing interfaces rather than specific types, well-designed code improves its flexibility by allowing polymorphic substitution. Duck-typing avoids tests using type() or isinstance(). (Note, however, that duck-typing can be complemented with abstract base classes.) Instead, it typically employs hasattr() tests or EAFP programming.

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EAFP Easier to ask for forgiveness than permission. This common Python coding style assumes the existence of valid keys or attributes and catches exceptions if the assumption proves false. This clean and fast style is characterized by the presence of many try and except statements. The technique contrasts with the LBYL style common to many other languages such as C. expression A piece of syntax which can be evaluated to some value. In other words, an expression is an accumulation of expression elements like literals, names, attribute access, operators or function calls which all return a value. In contrast to many other languages, not all language constructs are expressions. There are also statements which cannot be used as expressions, such as if. Assignments are also statements, not expressions. extension module A module written in C or C++, using Python’s C API to interact with the core and with user code. file object An object exposing a file-oriented API (with methods such as read() or write()) to an underlying resource. Depending on the way it was created, a file object can mediate access to a real on-disk file or to another other type of storage or communication device (for example standard input/output, in-memory buffers, sockets, pipes, etc.). File objects are also called file-like objects or streams. There are actually three categories of file objects: raw binary files, buffered binary files and text files. Their interfaces are defined in the io module. The canonical way to create a file object is by using the open() function. file-like object A synonym for file object. finder An object that tries to find the loader for a module. It must implement a method named find_module(). See PEP 302 for details and importlib.abc.Finder for an abstract base class. floor division Mathematical division that rounds down to nearest integer. The floor division operator is //. For example, the expression 11 // 4 evaluates to 2 in contrast to the 2.75 returned by float true division. Note that (-11) // 4 is -3 because that is -2.75 rounded downward. See PEP 238. function A series of statements which returns some value to a caller. It can also be passed zero or more arguments which may be used in the execution of the body. See also argument and method. __future__ A pseudo-module which programmers can use to enable new language features which are not compatible with the current interpreter. By importing the __future__ module and evaluating its variables, you can see when a new feature was first added to the language and when it becomes the default: >>> import __future__ >>> __future__.division _Feature((2, 2, 0, ’alpha’, 2), (3, 0, 0, ’alpha’, 0), 8192) garbage collection The process of freeing memory when it is not used anymore. Python performs garbage collection via reference counting and a cyclic garbage collector that is able to detect and break reference cycles. generator A function which returns an iterator. It looks like a normal function except that it contains yield statements for producing a series a values usable in a for-loop or that can be retrieved one at a time with the next() function. Each yield temporarily suspends processing, remembering the location execution state (including local variables and pending try-statements). When the generator resumes, it picks-up where it left-off (in contrast to functions which start fresh on every invocation. generator expression An expression that returns a generator. It looks like a normal expression followed by a for expression defining a loop variable, range, and an optional if expression. The combined expression generates values for an enclosing function: >>> sum(i*i for i in range(10)) 285

# sum of squares 0, 1, 4, ... 81

GIL See global interpreter lock.

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global interpreter lock The mechanism used by the CPython interpreter to assure that only one thread executes Python bytecode at a time. This simplifies the CPython implementation by making the object model (including critical built-in types such as dict) implicitly safe against concurrent access. Locking the entire interpreter makes it easier for the interpreter to be multi-threaded, at the expense of much of the parallelism afforded by multi-processor machines. However, some extension modules, either standard or third-party, are designed so as to release the GIL when doing computationally-intensive tasks such as compression or hashing. Also, the GIL is always released when doing I/O. Past efforts to create a “free-threaded” interpreter (one which locks shared data at a much finer granularity) have not been successful because performance suffered in the common single-processor case. It is believed that overcoming this performance issue would make the implementation much more complicated and therefore costlier to maintain. hashable An object is hashable if it has a hash value which never changes during its lifetime (it needs a __hash__() method), and can be compared to other objects (it needs an __eq__() method). Hashable objects which compare equal must have the same hash value. Hashability makes an object usable as a dictionary key and a set member, because these data structures use the hash value internally. All of Python’s immutable built-in objects are hashable, while no mutable containers (such as lists or dictionaries) are. Objects which are instances of user-defined classes are hashable by default; they all compare unequal, and their hash value is their id(). IDLE An Integrated Development Environment for Python. IDLE is a basic editor and interpreter environment which ships with the standard distribution of Python. immutable An object with a fixed value. Immutable objects include numbers, strings and tuples. Such an object cannot be altered. A new object has to be created if a different value has to be stored. They play an important role in places where a constant hash value is needed, for example as a key in a dictionary. importer An object that both finds and loads a module; both a finder and loader object. interactive Python has an interactive interpreter which means you can enter statements and expressions at the interpreter prompt, immediately execute them and see their results. Just launch python with no arguments (possibly by selecting it from your computer’s main menu). It is a very powerful way to test out new ideas or inspect modules and packages (remember help(x)). interpreted Python is an interpreted language, as opposed to a compiled one, though the distinction can be blurry because of the presence of the bytecode compiler. This means that source files can be run directly without explicitly creating an executable which is then run. Interpreted languages typically have a shorter development/debug cycle than compiled ones, though their programs generally also run more slowly. See also interactive. iterable A container object capable of returning its members one at a time. Examples of iterables include all sequence types (such as list, str, and tuple) and some non-sequence types like dict and file and objects of any classes you define with an __iter__() or __getitem__() method. Iterables can be used in a for loop and in many other places where a sequence is needed (zip(), map(), ...). When an iterable object is passed as an argument to the built-in function iter(), it returns an iterator for the object. This iterator is good for one pass over the set of values. When using iterables, it is usually not necessary to call iter() or deal with iterator objects yourself. The for statement does that automatically for you, creating a temporary unnamed variable to hold the iterator for the duration of the loop. See also iterator, sequence, and generator. iterator An object representing a stream of data. Repeated calls to the iterator’s __next__() method (or passing it to the built-in function next()) return successive items in the stream. When no more data are available a StopIteration exception is raised instead. At this point, the iterator object is exhausted and any further calls to its __next__() method just raise StopIteration again. Iterators are required to have an __iter__() method that returns the iterator object itself so every iterator is also iterable and may be used in most places where other iterables are accepted. One notable exception is code which attempts multiple iteration

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passes. A container object (such as a list) produces a fresh new iterator each time you pass it to the iter() function or use it in a for loop. Attempting this with an iterator will just return the same exhausted iterator object used in the previous iteration pass, making it appear like an empty container. More information can be found in Iterator Types (in The Python Library Reference). key function A key function or collation function is a callable that returns a value used for sorting or ordering. For example, locale.strxfrm() is used to produce a sort key that is aware of locale specific sort conventions. A number of tools in Python accept key functions to control how elements are ordered or grouped. They include min(), max(), sorted(), list.sort(), heapq.nsmallest(), heapq.nlargest(), and itertools.groupby(). There are several ways to create a key function. For example. the str.lower() method can serve as a key function for case insensitive sorts. Alternatively, an ad-hoc key function can be built from a lambda expression such as lambda r: (r[0], r[2]). Also, the operator module provides three key function constuctors: attrgetter(), itemgetter(), and methodcaller(). See the Sorting HOW TO (in ) for examples of how to create and use key functions. keyword argument Arguments which are preceded with a variable_name= in the call. The variable name designates the local name in the function to which the value is assigned. ** is used to accept or pass a dictionary of keyword arguments. See argument. lambda An anonymous inline function consisting of a single expression which is evaluated when the function is called. The syntax to create a lambda function is lambda [arguments]: expression LBYL Look before you leap. This coding style explicitly tests for pre-conditions before making calls or lookups. This style contrasts with the EAFP approach and is characterized by the presence of many if statements. list A built-in Python sequence. Despite its name it is more akin to an array in other languages than to a linked list since access to elements are O(1). list comprehension A compact way to process all or part of the elements in a sequence and return a list with the results. result = [’{:#04x}’.format(x) for x in range(256) if x % 2 == 0] generates a list of strings containing even hex numbers (0x..) in the range from 0 to 255. The if clause is optional. If omitted, all elements in range(256) are processed. loader An object that loads a module. It must define a method named load_module(). A loader is typically returned by a finder. See PEP 302 for details and importlib.abc.Loader for an abstract base class. mapping A container object (such as dict) which supports arbitrary key lookups using the special method __getitem__(). Mappings also support __len__(), __iter__(), and __contains__(). metaclass The class of a class. Class definitions create a class name, a class dictionary, and a list of base classes. The metaclass is responsible for taking those three arguments and creating the class. Most object oriented programming languages provide a default implementation. What makes Python special is that it is possible to create custom metaclasses. Most users never need this tool, but when the need arises, metaclasses can provide powerful, elegant solutions. They have been used for logging attribute access, adding thread-safety, tracking object creation, implementing singletons, and many other tasks. More information can be found in Customizing class creation (in The Python Language Reference). method A function which is defined inside a class body. If called as an attribute of an instance of that class, the method will get the instance object as its first argument (which is usually called self). See function and nested scope. mutable Mutable objects can change their value but keep their id(). See also immutable. named tuple Any tuple-like class whose indexable elements are also accessible using named attributes (for example, time.localtime() returns a tuple-like object where the year is accessible either with an index such as t[0] or with a named attribute like t.tm_year).

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A named tuple can be a built-in type such as time.struct_time, or it can be created with a regular class definition. A full featured named tuple can also be created with the factory function collections.namedtuple(). The latter approach automatically provides extra features such as a selfdocumenting representation like Employee(name=’jones’, title=’programmer’). namespace The place where a variable is stored. Namespaces are implemented as dictionaries. There are the local, global and built-in namespaces as well as nested namespaces in objects (in methods). Namespaces support modularity by preventing naming conflicts. For instance, the functions builtins.open() and os.open() are distinguished by their namespaces. Namespaces also aid readability and maintainability by making it clear which module implements a function. For instance, writing random.seed() or itertools.izip() makes it clear that those functions are implemented by the random and itertools modules, respectively. nested scope The ability to refer to a variable in an enclosing definition. For instance, a function defined inside another function can refer to variables in the outer function. Note that nested scopes by default work only for reference and not for assignment. Local variables both read and write in the innermost scope. Likewise, global variables read and write to the global namespace. The nonlocal allows writing to outer scopes. new-style class Old name for the flavor of classes now used for all class objects. In earlier Python versions, only new-style classes could use Python’s newer, versatile features like __slots__, descriptors, properties, __getattribute__(), class methods, and static methods. object Any data with state (attributes or value) and defined behavior (methods). Also the ultimate base class of any new-style class. positional argument The arguments assigned to local names inside a function or method, determined by the order in which they were given in the call. * is used to either accept multiple positional arguments (when in the definition), or pass several arguments as a list to a function. See argument. Python 3000 Nickname for the Python 3.x release line (coined long ago when the release of version 3 was something in the distant future.) This is also abbreviated “Py3k”. Pythonic An idea or piece of code which closely follows the most common idioms of the Python language, rather than implementing code using concepts common to other languages. For example, a common idiom in Python is to loop over all elements of an iterable using a for statement. Many other languages don’t have this type of construct, so people unfamiliar with Python sometimes use a numerical counter instead: for i in range(len(food)): print(food[i]) As opposed to the cleaner, Pythonic method: for piece in food: print(piece) reference count The number of references to an object. When the reference count of an object drops to zero, it is deallocated. Reference counting is generally not visible to Python code, but it is a key element of the CPython implementation. The sys module defines a getrefcount() function that programmers can call to return the reference count for a particular object. __slots__ A declaration inside a class that saves memory by pre-declaring space for instance attributes and eliminating instance dictionaries. Though popular, the technique is somewhat tricky to get right and is best reserved for rare cases where there are large numbers of instances in a memory-critical application. sequence An iterable which supports efficient element access using integer indices via the __getitem__() special method and defines a len() method that returns the length of the sequence. Some built-in sequence types are list, str, tuple, and bytes. Note that dict also supports __getitem__() and __len__(), but is considered a mapping rather than a sequence because the lookups use arbitrary immutable keys rather than integers. slice An object usually containing a portion of a sequence. A slice is created using the subscript notation, [] with colons between numbers when several are given, such as in variable_name[1:3:5]. The bracket

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(subscript) notation uses slice objects internally. special method A method that is called implicitly by Python to execute a certain operation on a type, such as addition. Such methods have names starting and ending with double underscores. Special methods are documented in Special method names (in The Python Language Reference). statement A statement is part of a suite (a “block” of code). A statement is either an expression or a one of several constructs with a keyword, such as if, while or for. triple-quoted string A string which is bound by three instances of either a quotation mark (“) or an apostrophe (‘). While they don’t provide any functionality not available with single-quoted strings, they are useful for a number of reasons. They allow you to include unescaped single and double quotes within a string and they can span multiple lines without the use of the continuation character, making them especially useful when writing docstrings. type The type of a Python object determines what kind of object it is; every object has a type. An object’s type is accessible as its __class__ attribute or can be retrieved with type(obj). view The objects returned from dict.keys(), dict.values(), and dict.items() are called dictionary views. They are lazy sequences that will see changes in the underlying dictionary. To force the dictionary view to become a full list use list(dictview). See Dictionary view objects (in The Python Library Reference). virtual machine A computer defined entirely in software. Python’s virtual machine executes the bytecode emitted by the bytecode compiler. Zen of Python Listing of Python design principles and philosophies that are helpful in understanding and using the language. The listing can be found by typing “import this” at the interactive prompt.

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B

ABOUT THESE DOCUMENTS These documents are generated from reStructuredText sources by Sphinx, a document processor specifically written for the Python documentation. Development of the documentation and its toolchain takes place on the docs@python.org mailing list. We’re always looking for volunteers wanting to help with the docs, so feel free to send a mail there! Many thanks go to: • Fred L. Drake, Jr., the creator of the original Python documentation toolset and writer of much of the content; • the Docutils project for creating reStructuredText and the Docutils suite; • Fredrik Lundh for his Alternative Python Reference project from which Sphinx got many good ideas. See Reporting Bugs for information how to report bugs in this documentation, or Python itself.

B.1 Contributors to the Python Documentation This section lists people who have contributed in some way to the Python documentation. It is probably not complete – if you feel that you or anyone else should be on this list, please let us know (send email to docs@python.org), and we’ll be glad to correct the problem. Aahz, Michael Abbott, Steve Alexander, Jim Ahlstrom, Fred Allen, A. Amoroso, Pehr Anderson, Oliver Andrich, Heidi Annexstad, Jesús Cea Avión, Manuel Balsera, Daniel Barclay, Chris Barker, Don Bashford, Anthony Baxter, Alexander Belopolsky, Bennett Benson, Jonathan Black, Robin Boerdijk, Michal Bozon, Aaron Brancotti, Georg Brandl, Keith Briggs, Ian Bruntlett, Lee Busby, Lorenzo M. Catucci, Carl Cerecke, Mauro Cicognini, Gilles Civario, Mike Clarkson, Steve Clift, Dave Cole, Matthew Cowles, Jeremy Craven, Andrew Dalke, Ben Darnell, L. Peter Deutsch, Robert Donohue, Fred L. Drake, Jr., Jacques Ducasse, Josip Dzolonga, Jeff Epler, Michael Ernst, Blame Andy Eskilsson, Carey Evans, Martijn Faassen, Carl Feynman, Dan Finnie, Hernán Martínez Foffani, Stefan Franke, Jim Fulton, Peter Funk, Lele Gaifax, Matthew Gallagher, Gabriel Genellina, Ben Gertzfield, Nadim Ghaznavi, Jonathan Giddy, Matt Giuca, Shelley Gooch, Nathaniel Gray, Grant Griffin, Thomas Guettler, Anders Hammarquist, Mark Hammond, Harald Hanche-Olsen, Manus Hand, Gerhard Häring, Travis B. Hartwell, Tim Hatch, Janko Hauser, Thomas Heller, Bernhard Herzog, Magnus L. Hetland, Konrad Hinsen, Stefan Hoffmeister, Albert Hofkamp, Gregor Hoffleit, Steve Holden, Thomas Holenstein, Gerrit Holl, Rob Hooft, Brian Hooper, Randall Hopper, Michael Hudson, Eric Huss, Jeremy Hylton, Roger Irwin, Jack Jansen, Philip H. Jensen, Pedro Diaz Jimenez, Kent Johnson, Lucas de Jonge, Andreas Jung, Robert Kern, Jim Kerr, Jan Kim, Greg Kochanski, Guido Kollerie, Peter A. Koren, Daniel Kozan, Andrew M. Kuchling, Dave Kuhlman, Erno Kuusela, Thomas Lamb, Detlef Lannert, Piers Lauder, Glyph Lefkowitz, Robert Lehmann, Marc-André Lemburg, Ross Light, Ulf A. Lindgren, Everett Lipman, Mirko Liss, Martin von Löwis, Fredrik Lundh, Jeff MacDonald, John Machin, Andrew MacIntyre, Vladimir Marangozov, Vincent Marchetti, Laura Matson, Daniel May, Rebecca McCreary, Doug Mennella, Paolo Milani, Skip Montanaro, Paul Moore, Ross Moore, Sjoerd Mullender, Dale Nagata, Ng Pheng Siong, Koray Oner, Tomas Oppelstrup, Denis S. Otkidach, Zooko O’Whielacronx, Shriphani Palakodety, William Park, Joonas Paalasmaa, Harri Pasanen, Bo Peng, Tim 81


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Peters, Benjamin Peterson, Christopher Petrilli, Justin D. Pettit, Chris Phoenix, François Pinard, Paul Prescod, Eric S. Raymond, Edward K. Ream, Terry J. Reedy, Sean Reifschneider, Bernhard Reiter, Armin Rigo, Wes Rishel, Armin Ronacher, Jim Roskind, Guido van Rossum, Donald Wallace Rouse II, Mark Russell, Nick Russo, Chris Ryland, Constantina S., Hugh Sasse, Bob Savage, Scott Schram, Neil Schemenauer, Barry Scott, Joakim Sernbrant, Justin Sheehy, Charlie Shepherd, SilentGhost, Michael Simcich, Ionel Simionescu, Michael Sloan, Gregory P. Smith, Roy Smith, Clay Spence, Nicholas Spies, Tage Stabell-Kulo, Frank Stajano, Anthony Starks, Greg Stein, Peter Stoehr, Mark Summerfield, Reuben Sumner, Kalle Svensson, Jim Tittsler, David Turner, Ville Vainio, Martijn Vries, Charles G. Waldman, Greg Ward, Barry Warsaw, Corran Webster, Glyn Webster, Bob Weiner, Eddy Welbourne, Jeff Wheeler, Mats Wichmann, Gerry Wiener, Timothy Wild, Collin Winter, Blake Winton, Dan Wolfe, Steven Work, Thomas Wouters, Ka-Ping Yee, Rory Yorke, Moshe Zadka, Milan Zamazal, Cheng Zhang, Trent Nelson, Michael Foord. It is only with the input and contributions of the Python community that Python has such wonderful documentation – Thank You!

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C

HISTORY AND LICENSE C.1 History of the software Python was created in the early 1990s by Guido van Rossum at Stichting Mathematisch Centrum (CWI, see http://www.cwi.nl/) in the Netherlands as a successor of a language called ABC. Guido remains Python’s principal author, although it includes many contributions from others. In 1995, Guido continued his work on Python at the Corporation for National Research Initiatives (CNRI, see http://www.cnri.reston.va.us/) in Reston, Virginia where he released several versions of the software. In May 2000, Guido and the Python core development team moved to BeOpen.com to form the BeOpen PythonLabs team. In October of the same year, the PythonLabs team moved to Digital Creations (now Zope Corporation; see http://www.zope.com/). In 2001, the Python Software Foundation (PSF, see http://www.python.org/psf/) was formed, a non-profit organization created specifically to own Python-related Intellectual Property. Zope Corporation is a sponsoring member of the PSF. All Python releases are Open Source (see http://www.opensource.org/ for the Open Source Definition). Historically, most, but not all, Python releases have also been GPL-compatible; the table below summarizes the various releases. Release 0.9.0 thru 1.2 1.3 thru 1.5.2 1.6 2.0 1.6.1 2.1 2.0.1 2.1.1 2.2 2.1.2 2.1.3 2.2.1 2.2.2 2.2.3 2.3 2.3.1 2.3.2 2.3.3 2.3.4 2.3.5 2.4

Derived from n/a 1.2 1.5.2 1.6 1.6 2.0+1.6.1 2.0+1.6.1 2.1+2.0.1 2.1.1 2.1.1 2.1.2 2.2 2.2.1 2.2.2 2.2.2 2.3 2.3.1 2.3.2 2.3.3 2.3.4 2.3

Year 1991-1995 1995-1999 2000 2000 2001 2001 2001 2001 2001 2002 2002 2002 2002 2002-2003 2002-2003 2002-2003 2003 2003 2004 2005 2004

Owner GPL compatible? CWI yes CNRI yes CNRI no BeOpen.com no CNRI no PSF no PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes PSF yes Continued on next page 83


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2.4.1 2.4.2 2.4.3 2.4.4 2.5 2.5.1 2.6 2.6.1 2.6.2 2.6.3 2.6.4 3.0 3.0.1 3.1 3.1.1

Table C.1 – continued from previous page 2.4 2005 PSF yes 2.4.1 2005 PSF yes 2.4.2 2006 PSF yes 2.4.3 2006 PSF yes 2.4 2006 PSF yes 2.5 2007 PSF yes 2.5 2008 PSF yes 2.6 2008 PSF yes 2.6.1 2009 PSF yes 2.6.2 2009 PSF yes 2.6.3 2009 PSF yes 2.6 2008 PSF yes 3.0 2009 PSF yes 3.0.1 2009 PSF yes 3.1 2009 PSF yes

Note: GPL-compatible doesn’t mean that we’re distributing Python under the GPL. All Python licenses, unlike the GPL, let you distribute a modified version without making your changes open source. The GPL-compatible licenses make it possible to combine Python with other software that is released under the GPL; the others don’t. Thanks to the many outside volunteers who have worked under Guido’s direction to make these releases possible.

C.2 Terms and conditions for accessing or otherwise using Python PSF LICENSE AGREEMENT FOR PYTHON 3.1.3 1. This LICENSE AGREEMENT is between the Python Software Foundation (“PSF”), and the Individual or Organization (“Licensee”) accessing and otherwise using Python 3.1.3 software in source or binary form and its associated documentation. 2. Subject to the terms and conditions of this License Agreement, PSF hereby grants Licensee a nonexclusive, royalty-free, world-wide license to reproduce, analyze, test, perform and/or display publicly, prepare derivative works, distribute, and otherwise use Python 3.1.3 alone or in any derivative version, provided, however, that PSF’s License Agreement and PSF’s notice of copyright, i.e., “Copyright © 2001-2010 Python Software Foundation; All Rights Reserved” are retained in Python 3.1.3 alone or in any derivative version prepared by Licensee. 3. In the event Licensee prepares a derivative work that is based on or incorporates Python 3.1.3 or any part thereof, and wants to make the derivative work available to others as provided herein, then Licensee hereby agrees to include in any such work a brief summary of the changes made to Python 3.1.3. 4. PSF is making Python 3.1.3 available to Licensee on an “AS IS” basis. PSF MAKES NO REPRESENTATIONS OR WARRANTIES, EXPRESS OR IMPLIED. BY WAY OF EXAMPLE, BUT NOT LIMITATION, PSF MAKES NO AND DISCLAIMS ANY REPRESENTATION OR WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE OR THAT THE USE OF PYTHON 3.1.3 WILL NOT INFRINGE ANY THIRD PARTY RIGHTS. 5. PSF SHALL NOT BE LIABLE TO LICENSEE OR ANY OTHER USERS OF PYTHON 3.1.3 FOR ANY INCIDENTAL, SPECIAL, OR CONSEQUENTIAL DAMAGES OR LOSS AS A RESULT OF MODIFYING, DISTRIBUTING, OR OTHERWISE USING PYTHON 3.1.3, OR ANY DERIVATIVE THEREOF, EVEN IF ADVISED OF THE POSSIBILITY THEREOF. 6. This License Agreement will automatically terminate upon a material breach of its terms and conditions.

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7. Nothing in this License Agreement shall be deemed to create any relationship of agency, partnership, or joint venture between PSF and Licensee. This License Agreement does not grant permission to use PSF trademarks or trade name in a trademark sense to endorse or promote products or services of Licensee, or any third party. 8. By copying, installing or otherwise using Python 3.1.3, Licensee agrees to be bound by the terms and conditions of this License Agreement. BEOPEN.COM LICENSE AGREEMENT FOR PYTHON 2.0 BEOPEN PYTHON OPEN SOURCE LICENSE AGREEMENT VERSION 1 1. This LICENSE AGREEMENT is between BeOpen.com (“BeOpen”), having an office at 160 Saratoga Avenue, Santa Clara, CA 95051, and the Individual or Organization (“Licensee”) accessing and otherwise using this software in source or binary form and its associated documentation (“the Software”). 2. Subject to the terms and conditions of this BeOpen Python License Agreement, BeOpen hereby grants Licensee a non-exclusive, royalty-free, world-wide license to reproduce, analyze, test, perform and/or display publicly, prepare derivative works, distribute, and otherwise use the Software alone or in any derivative version, provided, however, that the BeOpen Python License is retained in the Software, alone or in any derivative version prepared by Licensee. 3. BeOpen is making the Software available to Licensee on an “AS IS” basis. BEOPEN MAKES NO REPRESENTATIONS OR WARRANTIES, EXPRESS OR IMPLIED. BY WAY OF EXAMPLE, BUT NOT LIMITATION, BEOPEN MAKES NO AND DISCLAIMS ANY REPRESENTATION OR WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE OR THAT THE USE OF THE SOFTWARE WILL NOT INFRINGE ANY THIRD PARTY RIGHTS. 4. BEOPEN SHALL NOT BE LIABLE TO LICENSEE OR ANY OTHER USERS OF THE SOFTWARE FOR ANY INCIDENTAL, SPECIAL, OR CONSEQUENTIAL DAMAGES OR LOSS AS A RESULT OF USING, MODIFYING OR DISTRIBUTING THE SOFTWARE, OR ANY DERIVATIVE THEREOF, EVEN IF ADVISED OF THE POSSIBILITY THEREOF. 5. This License Agreement will automatically terminate upon a material breach of its terms and conditions. 6. This License Agreement shall be governed by and interpreted in all respects by the law of the State of California, excluding conflict of law provisions. Nothing in this License Agreement shall be deemed to create any relationship of agency, partnership, or joint venture between BeOpen and Licensee. This License Agreement does not grant permission to use BeOpen trademarks or trade names in a trademark sense to endorse or promote products or services of Licensee, or any third party. As an exception, the “BeOpen Python” logos available at http://www.pythonlabs.com/logos.html may be used according to the permissions granted on that web page. 7. By copying, installing or otherwise using the software, Licensee agrees to be bound by the terms and conditions of this License Agreement. CNRI LICENSE AGREEMENT FOR PYTHON 1.6.1 1. This LICENSE AGREEMENT is between the Corporation for National Research Initiatives, having an office at 1895 Preston White Drive, Reston, VA 20191 (“CNRI”), and the Individual or Organization (“Licensee”) accessing and otherwise using Python 1.6.1 software in source or binary form and its associated documentation. 2. Subject to the terms and conditions of this License Agreement, CNRI hereby grants Licensee a nonexclusive, royalty-free, world-wide license to reproduce, analyze, test, perform and/or display publicly, prepare derivative works, distribute, and otherwise use Python 1.6.1 alone or in any derivative version, provided, however, that CNRI’s License Agreement and CNRI’s notice of copyright, i.e., “Copyright © 1995-2001 Corporation for National Research Initiatives; All Rights Reserved” are retained in Python 1.6.1 alone or in any derivative version prepared by Licensee. Alternately, in lieu of CNRI’s License Agreement, Licensee may substitute the following text (omitting the quotes): “Python 1.6.1 is made available subject to the terms and conditions in CNRI’s License Agreement. This Agreement together with Python 1.6.1 may be located on the Internet using the following unique, persistent identifier (known as a handle): 1895.22/1013. This Agreement may also be obtained from a proxy server on the Internet using the following URL: http://hdl.handle.net/1895.22/1013.”

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3. In the event Licensee prepares a derivative work that is based on or incorporates Python 1.6.1 or any part thereof, and wants to make the derivative work available to others as provided herein, then Licensee hereby agrees to include in any such work a brief summary of the changes made to Python 1.6.1. 4. CNRI is making Python 1.6.1 available to Licensee on an “AS IS” basis. CNRI MAKES NO REPRESENTATIONS OR WARRANTIES, EXPRESS OR IMPLIED. BY WAY OF EXAMPLE, BUT NOT LIMITATION, CNRI MAKES NO AND DISCLAIMS ANY REPRESENTATION OR WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE OR THAT THE USE OF PYTHON 1.6.1 WILL NOT INFRINGE ANY THIRD PARTY RIGHTS. 5. CNRI SHALL NOT BE LIABLE TO LICENSEE OR ANY OTHER USERS OF PYTHON 1.6.1 FOR ANY INCIDENTAL, SPECIAL, OR CONSEQUENTIAL DAMAGES OR LOSS AS A RESULT OF MODIFYING, DISTRIBUTING, OR OTHERWISE USING PYTHON 1.6.1, OR ANY DERIVATIVE THEREOF, EVEN IF ADVISED OF THE POSSIBILITY THEREOF. 6. This License Agreement will automatically terminate upon a material breach of its terms and conditions. 7. This License Agreement shall be governed by the federal intellectual property law of the United States, including without limitation the federal copyright law, and, to the extent such U.S. federal law does not apply, by the law of the Commonwealth of Virginia, excluding Virginia’s conflict of law provisions. Notwithstanding the foregoing, with regard to derivative works based on Python 1.6.1 that incorporate non-separable material that was previously distributed under the GNU General Public License (GPL), the law of the Commonwealth of Virginia shall govern this License Agreement only as to issues arising under or with respect to Paragraphs 4, 5, and 7 of this License Agreement. Nothing in this License Agreement shall be deemed to create any relationship of agency, partnership, or joint venture between CNRI and Licensee. This License Agreement does not grant permission to use CNRI trademarks or trade name in a trademark sense to endorse or promote products or services of Licensee, or any third party. 8. By clicking on the “ACCEPT” button where indicated, or by copying, installing or otherwise using Python 1.6.1, Licensee agrees to be bound by the terms and conditions of this License Agreement. ACCEPT CWI LICENSE AGREEMENT FOR PYTHON 0.9.0 THROUGH 1.2 Copyright © 1991 - 1995, Stichting Mathematisch Centrum Amsterdam, The Netherlands. All rights reserved. Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Stichting Mathematisch Centrum or CWI not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. STICHTING MATHEMATISCH CENTRUM DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL STICHTING MATHEMATISCH CENTRUM BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

C.3 Licenses and Acknowledgements for Incorporated Software This section is an incomplete, but growing list of licenses and acknowledgements for third-party software incorporated in the Python distribution.

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C.3.1 Mersenne Twister The _random module includes code based on a download from http://www.math.keio.ac.jp/ matumoto/MT2002/emt19937ar.html. The following are the verbatim comments from the original code: A C-program for MT19937, with initialization improved 2002/1/26. Coded by Takuji Nishimura and Makoto Matsumoto. Before using, initialize the state by using init_genrand(seed) or init_by_array(init_key, key_length). Copyright (C) 1997 - 2002, Makoto Matsumoto and Takuji Nishimura, All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. The names of its contributors may not be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

Any feedback is very welcome. http://www.math.keio.ac.jp/matumoto/emt.html email: matumoto@math.keio.ac.jp

C.3.2 Sockets The socket module uses the functions, getaddrinfo(), and getnameinfo(), which are coded in separate source files from the WIDE Project, http://www.wide.ad.jp/. Copyright (C) 1995, 1996, 1997, and 1998 WIDE Project. All rights reserved.

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Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the name of the project nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE PROJECT AND CONTRIBUTORS ‘‘AS IS’’ AND GAI_ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE PROJECT OR CONTRIBUTORS BE LIABLE FOR GAI_ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON GAI_ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN GAI_ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

C.3.3 Floating point exception control The source for the fpectl module includes the following notice: --------------------------------------------------------------------/ Copyright (c) 1996. \ | The Regents of the University of California. | | All rights reserved. | | | | Permission to use, copy, modify, and distribute this software for | | any purpose without fee is hereby granted, provided that this en| | tire notice is included in all copies of any software which is or | | includes a copy or modification of this software and in all | | copies of the supporting documentation for such software. | | | | This work was produced at the University of California, Lawrence | | Livermore National Laboratory under contract no. W-7405-ENG-48 | | between the U.S. Department of Energy and The Regents of the | | University of California for the operation of UC LLNL. | | | | DISCLAIMER | | | | This software was prepared as an account of work sponsored by an | | agency of the United States Government. Neither the United States | | Government nor the University of California nor any of their em| | ployees, makes any warranty, express or implied, or assumes any | | liability or responsibility for the accuracy, completeness, or | | usefulness of any information, apparatus, product, or process | | disclosed, or represents that its use would not infringe | | privately-owned rights. Reference herein to any specific commer| 88

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| | | | | | |

cial products, process, or service by trade name, trademark, | manufacturer, or otherwise, does not necessarily constitute or | imply its endorsement, recommendation, or favoring by the United | States Government or the University of California. The views and | opinions of authors expressed herein do not necessarily state or | reflect those of the United States Government or the University | of California, and shall not be used for advertising or product | \ endorsement purposes. / ---------------------------------------------------------------------

C.3.4 Asynchronous socket services The asynchat and asyncore modules contain the following notice: Copyright 1996 by Sam Rushing All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Sam Rushing not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. SAM RUSHING DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL SAM RUSHING BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

C.3.5 Cookie management The http.cookies module contains the following notice: Copyright 2000 by Timothy O’Malley <timo@alum.mit.edu> All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Timothy O’Malley not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. Timothy O’Malley DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS

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SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL Timothy O’Malley BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

C.3.6 Profiling The profile and pstats modules contain the following notice: Copyright 1994, by InfoSeek Corporation, all rights reserved. Written by James Roskind Permission to use, copy, modify, and distribute this Python software and its associated documentation for any purpose (subject to the restriction in the following sentence) without fee is hereby granted, provided that the above copyright notice appears in all copies, and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of InfoSeek not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. This permission is explicitly restricted to the copying and modification of the software to remain in Python, compiled Python, or other languages (such as C) wherein the modified or derived code is exclusively imported into a Python module. INFOSEEK CORPORATION DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL INFOSEEK CORPORATION BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

C.3.7 Execution tracing The trace module contains the following notice: portions copyright 2001, Autonomous Zones Industries, Inc., all rights... err... reserved and offered to the public under the terms of the Python 2.2 license. Author: Zooko O’Whielacronx http://zooko.com/ mailto:zooko@zooko.com Copyright 2000, Mojam Media, Inc., all rights reserved. Author: Skip Montanaro Copyright 1999, Bioreason, Inc., all rights reserved. Author: Andrew Dalke

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Copyright 1995-1997, Automatrix, Inc., all rights reserved. Author: Skip Montanaro Copyright 1991-1995, Stichting Mathematisch Centrum, all rights reserved.

Permission to use, copy, modify, and distribute this Python software and its associated documentation for any purpose without fee is hereby granted, provided that the above copyright notice appears in all copies, and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of neither Automatrix, Bioreason or Mojam Media be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission.

C.3.8 UUencode and UUdecode functions The uu module contains the following notice: Copyright 1994 by Lance Ellinghouse Cathedral City, California Republic, United States of America. All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Lance Ellinghouse not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. LANCE ELLINGHOUSE DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL LANCE ELLINGHOUSE CENTRUM BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. Modified by Jack Jansen, CWI, July 1995: - Use binascii module to do the actual line-by-line conversion between ascii and binary. This results in a 1000-fold speedup. The C version is still 5 times faster, though. - Arguments more compliant with Python standard

C.3.9 XML Remote Procedure Calls The xmlrpc.client module contains the following notice: The XML-RPC client interface is Copyright (c) 1999-2002 by Secret Labs AB Copyright (c) 1999-2002 by Fredrik Lundh By obtaining, using, and/or copying this software and/or its associated documentation, you agree that you have read, understood,

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and will comply with the following terms and conditions: Permission to use, copy, modify, and distribute this software and its associated documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appears in all copies, and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Secret Labs AB or the author not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. SECRET LABS AB AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL SECRET LABS AB OR THE AUTHOR BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

C.3.10 test_epoll The test_epoll contains the following notice: Copyright (c) 2001-2006 Twisted Matrix Laboratories. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

C.3.11 Select kqueue The select and contains the following notice for the kqueue interface: Copyright (c) 2000 Doug White, 2006 James Knight, 2007 Christian Heimes All rights reserved. Redistribution and use in source and binary forms, with or without

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modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ‘‘AS IS’’ AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

C.3.12 strtod and dtoa The file Python/dtoa.c, which supplies C functions dtoa and strtod for conversion of C doubles to and from strings, is derived from the file of the same name by David M. Gay, currently available from http://www.netlib.org/fp/. The original file, as retrieved on March 16, 2009, contains the following copyright and licensing notice: /**************************************************************** * * The author of this software is David M. Gay. * * Copyright (c) 1991, 2000, 2001 by Lucent Technologies. * * Permission to use, copy, modify, and distribute this software for any * purpose without fee is hereby granted, provided that this entire notice * is included in all copies of any software which is or includes a copy * or modification of this software and in all copies of the supporting * documentation for such software. * * THIS SOFTWARE IS BEING PROVIDED "AS IS", WITHOUT ANY EXPRESS OR IMPLIED * WARRANTY. IN PARTICULAR, NEITHER THE AUTHOR NOR LUCENT MAKES ANY * REPRESENTATION OR WARRANTY OF ANY KIND CONCERNING THE MERCHANTABILITY * OF THIS SOFTWARE OR ITS FITNESS FOR ANY PARTICULAR PURPOSE. * ***************************************************************/

C.3.13 OpenSSL The modules hashlib, posix, ssl, crypt use the OpenSSL library for added performance if made available by the operating system. Additionally, the Windows installers for Python include a copy of the OpenSSL libraries, so we include a copy of the OpenSSL license here: LICENSE ISSUES ==============

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The OpenSSL toolkit stays under a dual license, i.e. both the conditions of the OpenSSL License and the original SSLeay license apply to the toolkit. See below for the actual license texts. Actually both licenses are BSD-style Open Source licenses. In case of any license issues related to OpenSSL please contact openssl-core@openssl.org. OpenSSL License --------------/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * 94

==================================================================== Copyright (c) 1998-2008 The OpenSSL Project. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. All advertising materials mentioning features or use of this software must display the following acknowledgment: "This product includes software developed by the OpenSSL Project for use in the OpenSSL Toolkit. (http://www.openssl.org/)" 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to endorse or promote products derived from this software without prior written permission. For written permission, please contact openssl-core@openssl.org. 5. Products derived from this software may not be called "OpenSSL" nor may "OpenSSL" appear in their names without prior written permission of the OpenSSL Project. 6. Redistributions of any form whatsoever must retain the following acknowledgment: "This product includes software developed by the OpenSSL Project for use in the OpenSSL Toolkit (http://www.openssl.org/)" THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ‘‘AS IS’’ AND ANY EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE OpenSSL PROJECT OR ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)

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* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. * ==================================================================== * * This product includes cryptographic software written by Eric Young * (eay@cryptsoft.com). This product includes software written by Tim * Hudson (tjh@cryptsoft.com). * */ Original SSLeay License ----------------------/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *

Copyright (C) 1995-1998 Eric Young (eay@cryptsoft.com) All rights reserved. This package is an SSL implementation written by Eric Young (eay@cryptsoft.com). The implementation was written so as to conform with Netscapes SSL. This library is free for commercial and non-commercial use as long as the following conditions are aheared to. The following conditions apply to all code found in this distribution, be it the RC4, RSA, lhash, DES, etc., code; not just the SSL code. The SSL documentation included with this distribution is covered by the same copyright terms except that the holder is Tim Hudson (tjh@cryptsoft.com). Copyright remains Eric Young’s, and as such any Copyright notices in the code are not to be removed. If this package is used in a product, Eric Young should be given attribution as the author of the parts of the library used. This can be in the form of a textual message at program startup or in documentation (online or textual) provided with the package. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. All advertising materials mentioning features or use of this software must display the following acknowledgement: "This product includes cryptographic software written by Eric Young (eay@cryptsoft.com)" The word ’cryptographic’ can be left out if the rouines from the library being used are not cryptographic related :-). 4. If you include any Windows specific code (or a derivative thereof) from the apps directory (application code) you must include an acknowledgement: "This product includes software written by Tim Hudson (tjh@cryptsoft.com)" THIS SOFTWARE IS PROVIDED BY ERIC YOUNG ‘‘AS IS’’ AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE

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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * The licence and distribution terms for any publically available version or * derivative of this code cannot be changed. i.e. this code cannot simply be * copied and put under another distribution licence * [including the GNU Public Licence.] */

C.3.14 expat The pyexpat extension is built using an included copy of the expat sources unless the build is configured --with-system-expat: Copyright (c) 1998, 1999, 2000 Thai Open Source Software Center Ltd and Clark Cooper Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

C.3.15 libffi The _ctypes extension is built using an included copy of the libffi sources unless the build is configured --with-system-libffi: Copyright (c) 1996-2008

Red Hat, Inc and others.

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the ‘‘Software’’), to deal in the Software without restriction, including

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without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED ‘‘AS IS’’, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

C.3.16 zlib The zlib extension is built using an included copy of the zlib sources unless the zlib version found on the system is too old to be used for the build: Copyright (C) 1995-2010 Jean-loup Gailly and Mark Adler This software is provided ’as-is’, without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. 3. This notice may not be removed or altered from any source distribution. Jean-loup Gailly jloup@gzip.org

Mark Adler madler@alumni.caltech.edu

C.3. Licenses and Acknowledgements for Incorporated Software

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Appendix C. History and License


APPENDIX

D

COPYRIGHT Python and this documentation is: Copyright © 2001-2010 Python Software Foundation. All rights reserved. Copyright © 2000 BeOpen.com. All rights reserved. Copyright © 1995-2000 Corporation for National Research Initiatives. All rights reserved. Copyright © 1991-1995 Stichting Mathematisch Centrum. All rights reserved.

See History and License for complete license and permissions information.

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Appendix D. Copyright


INDEX

Symbols

F

..., 73 __future__, 75 __slots__, 78 >>>, 73 2to3, 73

file object, 75 file-like object, 75 finalization, of objects, 53 finder, 75 floor division, 75 function, 75

A abstract base class, 73 argument, 73 attribute, 73

B BDFL, 73 built-in function repr, 53 str, 53 bytecode, 73

C class, 73 coercion, 73 complex number, 74 context manager, 74 CPython, 74

D deallocation, object, 53 decorator, 74 descriptor, 74 dictionary, 74 distutils.sysconfig module, 72 docstring, 74 duck-typing, 74

E EAFP, 74 expression, 75 extension module, 75

G garbage collection, 75 generator, 75 generator expression, 75 GIL, 75 global interpreter lock, 75

H hashable, 76

I IDLE, 76 immutable, 76 importer, 76 interactive, 76 interpreted, 76 iterable, 76 iterator, 76

K key function, 77 keyword argument, 77

L lambda, 77 LBYL, 77 list, 77 list comprehension, 77 loader, 77

M mapping, 77 metaclass, 77 101


Extending and Embedding Python, Release 3.1.3

method, 77 module distutils.sysconfig, 72 mutable, 77

virtual machine, 79

N

Z

named tuple, 77 namespace, 78 nested scope, 78 new-style class, 78

Zen of Python, 79

W WRITE_RESTRICTED, 55

O object, 78 deallocation, 53 finalization, 53

P Philbrick, Geoff, 12 positional argument, 78 PyArg_ParseTuple(), 11 PyArg_ParseTupleAndKeywords(), 12 PyErr_Fetch(), 53 PyErr_Restore(), 53 PyObject_CallObject(), 9 Python 3000, 78 Python Enhancement Proposals PEP 238, 75 PEP 302, 75, 77 PEP 343, 74 Pythonic, 78

R READ_RESTRICTED, 55 READONLY, 55 reference count, 78 repr built-in function, 53 RESTRICTED, 55

S sequence, 78 slice, 78 special method, 79 statement, 79 str built-in function, 53

T triple-quoted string, 79 type, 79

V view, 79

102

Index


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